NORTH-HOLLAND
MATHEMATICS STUDIES Notas de Matem6tica editor: Leopoldo Nachbin
Cohomology of Completions
SAUL LUBKIN
NORTH-HOLLAND
42
COHOMOLOGY OF COMPLETIONS
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NORTH-HOLLAND MATHEMATICS STUDIES Notas de Matematica (71) Editor: Leopoldo Nachbin Universidade Federal do Rio de Janeiro and University of Rochester
Cohomology of Completions
SAUL LUBKIN Department of Mathematics University of Rochester Rochester, N. Y. 14620, U.S.A.
1980
NORTH-HOLLAND PUBLISHING COMPANY - AMSTERDAM. NEW YORK. OXFORD
42
Il
North-Holland Publishing Company. 1980
All rights reserved. No part a/this publication may be reproduced. stored in a retrieval system, or transmilled. in any form or by any means. electronic. mechanical. photocopying. recording or otherwise. without the prior permission a/the copyright owner.
ISBN: 0444860428
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Library or Congress Cataloging in Publieallon Data
Lublrln. Saul., 1939Cohomology of completions. (Notas de matem&tica ; 71) (Noith-Holland mathematics studies ; 42) Bibliography: p. 1. Complexes. Cochain. 2. Modul.es (Algebra) 3. Spectral sequences (Mathematics) I. Title. II. Series. QAl.N86 no. 71 cQAl69J 5l0s C5l2'.55J 80-19364 ISBN 0-444-86042-8
PRINTED IN THE NETHERLANDS
To Laure, my wife
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PREFACE
In this book, we study, primarily, the cohomology of the t-adic completion of cochain complexes of left A-modules, where A
is a ring and
tEA.
To this end, in the Introduction, we develop the necessary basic homological techniques that are used throughout this book. The text is also filled with many examples and applications to, e.g., algebraic geometry and algebraic topology. For example, using the deep, basic finiteness theorem, Chapter 5, Theorem 1, we prove the finite generation of lifted p-adic cohomology "using the Noetherian
O-algebra
A,
/\"
of a scheme proper over a
see [P.A.C.].
This connects up with
research done by the author over the past seventeen years on the Weil zeta function stemming from the original Weil Conjectures, see e.g.,
[W.C.], [C.A.W.], [P.P.W.C.], [B.W.V.], [P.C.T.],
[F.G.P.R.] and [P.A.C.]. Also, the general theory of Poincare duality is studied somewhat in Chapter 7, and this is used, in algebraic geometry, to prove Poincare duality for the lifted p-adic cohomology of complete non-singular algebraic varieties, see [P.A.C.]; as well as applications to the more traditional case, in algebraic topology, of the usual singular cohomology of compact, oriented topological manifolds, see the Examples of Chapter 7. And, in Chapter 8, we easily retrieve, as another application to the field of algebraic geometry, most of the well-known theorems on the finite generation of the cohomology of formal schemes proper over an affine, for finitely generated ideals. The book is written in such a way that a graduate student, vii
viii
Preface
with very little other than basic background, and having only the most rudimentary knowledge of homology, should be able to profit from various parts of it.
And, in part towards this
end, there is an extensive Introduction. The first chapter of the Introduction covers the general theory of abelian categories and may be skipped by those readers who are not interested in that subject.
The second chapter of
the Introduction contains what is perhaps the most thorough study ever made of spectral sequences.
Yet, it is so written
that is should be accessible to a beginner in the subject. However, many researchers, even those who are very advanced in the subject, who have to study or construct new spectral sequences, at any level, may be able to profit from the general study made. The greater part of this book is written at the level of left modules over a ring, rather
than for the more general
abelian categories, so as to make the material more accessible to the beginner.
However, for the readers interested in the
greater generality, the first chapter of the Introduction supplies a thorough initiation to the general theory of abelian categories, including how to work in abelian categories. The chapter on spectral sequences, Chapter 2 of the Introduction, is written at the abstract level of abelian categorieshowever, consistent with the general philosophy, it has been written in such a fashion that the beginner can mentally substitute the words "abelian group" for "object", and "the category
A of abelian groups" for "an abelian category
A", throughout
that chapter, if his only interest is that concrete case.
Preface
ix
(Although, Introduction, Chapter 1, contains all the necessary background material on abelian categories, and more, if desired.)
Description of some selected results; applications. In the Introduction, Chapter 1, the
no~ion
of abelian
category is thoroughly developed, and it is shown how to prove theorems in an abstract abelian category.
In section 2, the
familiar notions of subobject and quotient-object are studied, and in section 3 abelian categories are introduced formally. Then, the previously published paper, "Imbedding of Abelian Categories", chapter.
([I.A.C.)) is reproduced, as section 4 of the
The reader learns, in this section, how to work, in
many ways, as freely in a general abstract abelian category, as in the category of left modules over a ring.
Also, in sec-
tion 5 of this chapter, the notion of a sUbquotient of an object in an abelian category (or of an abelian group) is defined formally and developed (for the first time to the best of the author's knowledge).
It is believed that this will facilitate
the understanding of the definition of the "Eoo-term" of a spectral sequence,
as in the next chapter.
(Another applica-
tion to algebraic topology, of this material (not discussed in the text) is a better understanding of the higher order cohomology operations, as in the
Steenrod algebra.)
In Chapter 2 of the Introduction, what is probably the most extensive study to appear so far, is made of the theory of spectral sequences.
However, this material is suitable to be
read by a graduate student who has not had too extensive a background.
To develop the theory properly, the general notion
Preface
x
of graded abelian category, is introduced in section 3.
Fil-
tered objects, and their completions and co-completions, are (E.g., in section 6 it is shown that,
studied in section 6.
whenever the completion of the co-completion, and the co-completion of the completion, of a filtered object both make sense, then they are canonically isomorphic.)
And the abutment, the
partial abutments, see section 7, the Eoo-term, etc., are all studied for the spectral sequence of an exact couple (section 7), the spectral sequence of a filtered cochain complex (section B)and the spectral sequence of a double complex (section 10) •
In sections 2 and 5, the spectral sequence of an exact couple is studied.
Among other things, one obtains a short
exact sequence, the middle term of which is
and the first
Eoo'
and third terms of which depend entirely on the "top object"
v
of the exact couple and the endomorphism
0<-
Ker (t) n (t] [ divisible part of V)
<-
<-I
E 00
V/(t-torsion) t.(V/t-torsion)
t
I
of
<-
V:
0 •
In section 7, the two partial abutments of the spectral sequence of a conventional, bigraded exact couple are defined and studied.
These are the direct limit abutments
anc the inverse limit abutments
"Hn, n E 7..
'Hn, nE 7. ,
These are two sets
of "would-be" abutments, and are filtered objects.
The associ-
ated gradeds of each of these sets is a different subquotient of
The delicate question of whether or not these par-
tial abutments are perfect is studied (e.g., in section 7, and in section 9, Theorem 4 and Corollary 4.1).
It is equivalent
to ask whether or not the left and right defects are zero
Preface
xi
(section 7). A conventional bigraded exact couple induces three in-
creasing subobjects, The right defect is the subobject
of the and the left defect
(In the category of abelian groups, the right defect-but not in general the left defect- is always zero.) The associated graded of the direct limit abutment is canonically isomorphic to
and the associated graded of
the inverse limit abutment is canonically isomorphic to C~,q/B~,q.
For the spectral sequence of a filtered cochain complex, we also construct the "best possible hope" for an abutment for a filtered cochain complex, the integrated partial abutments Hn,
nE 'l'.
These can be thought of as "tying together" the
direct limit and inverse limit abutmenGof the exact couple of the filtered cochain complex- in the precise sense that, the associated graded of the integrated partial abutments are canonically isomorphic to
see section 8.
And the
integrated partial abutments can also be thought of as "tying together" the dual partial abutments of the filtered cochain complex (section 8, Theorem 10).
In fact, there are four, in
general non-isomorphic, exact couples induced by a filtered cochain complex, all having the same spectral sequence (but in general different sets of partial abutments), see section 8. In section 9, Corollary 4.1, it is also shown that if the spectral sequence is such that the cycles stabilize, then the left defect=O, so that if we are in the cat. of abo gps., then
Preface
xii
the integ. part. abts. are a true abutment.
If also the
spectral sequence is semi-stable (see section 9, Remark 3 after Proposition 5.1), then the integrated partial abutments are also complete (section 9, Proposition 5).
(And then similar
observations also hold for the set of partial abutments, and also
for the dual set of partial abutments, of the completion
of the co-completion of the filtered cochain complex, see near the end of section 9).
The spectral sequence of a double
complex is studied in section 10.
And also, in section 10,
Example 3, the Adams spectral sequence is studied from a spectral sequence-theoretic point of view, as an interesting example from algebraic topology of an important spectral sequence coming from an exact couple in which the inverse limit abutments act as an abutment (in the sense of section 7, Definition 1), rather than the more common direct limit abutments. It is shown by Examples, that most of the pathology not excluded by the theories of Intro. Chap.2, actually do occur. Spectral Sequences were first introduced by J. Leray. After the Introduction, we begin the main theme of the book.
One can begin the book at this point, if one wishes,
looking back when necessary to the Introduction. Let
A
be a ring (not necessarily commutative) with
identi ty, and let Let
C*
t
~
A.
be any cochain complex of left A-modules, in-
dexed by all the integers.
all integers
n,
Then we have the cohomology groups,
which are left A-modules.
We also have the
Preface
xiii
groups
and also
all integers
n, i,
with
i > O.
We study the connections be-
tween these groups. In Chapter 1, we study the Bockstein spectral sequence. In particular, as a special case of Introduction, Chapter 2, section 5, we obtain a short exact sequence, the middle term and the first and last terms of which depend
of which is entirely on
Hn(C*)
and on
ter 1, Theorem 2).
Hn+l(C*)
respectively.
No hypotheses are required.
(Chap-
This essen-
tially determines the Ew-term of the Bockstein spectral sequence in the fullest generality. (It was, essentially, in the making of a study of these results, that I was led to the Introduction, Chapter 2.) In Chapter 2, we study an exact sequence of six terms, interconnecting n,i,
with
Hn(C*)
i > O.
for all integers
I introduced this sequence over thirteen
years ago in [P.P.W.C.], where it appeared as (1.8) (and the actual research had been done earlier, at the University of Oxford, in 1963-64).
We strengthen and improve slightly on
these previous results. In Chapter 3, a well known short exact sequence is noted, in the case that
n.
C
n
is t-adically complete for all integers
Preface
xiv
n C
In Chapter 4, we assume that tegers
n,
is complete for all in-
and use the results established in Chapters 1,2
3 to obtain some new results. Chapter 4.
and
Most striking is Theorem 6 of
See also Proposition 5, and Corollary 6.1 of Chap-
ter 4. In Chapter 5, we combine the results of Chapter 1 (especially Proposition 6) with those of Chapter 4 (especially Proposition 2 - a corollary of Theorem 1, which is a special case of Theorem 6) to obtain the theorem (Theorem 1) that gives the chapter its heading.
We state it here.
Chapter 5, Theorem 1. let A
t~
A
Let
A
be an element in the center of
is t-adically complete.
Let
C*
complex of left A-modules such that for all integers by
t":Ci+c
ring
A
be a ring with identity and
i
i,
A.
~-indexed)
be a c
i
Suppose that cochain
is t-adically complete
and that the endomorphism "multiplication
is injective, all integers
i.
Suppose that the
is left Noetherian (i.e., that all left ideals are
finitely generated.
This assumption can be deleted if we com-
plicate the statement of the Theorem somewhat- see the Remarks following Theorem 1 of Chapter 5). teger.
Let
n
be any fixed in-
Then if
Hn(C*/tC*)
is finitely generated as left (A/tA)-module,
for the fixed integer
n,
then Hn(C*)
is finitely generated as left A-module.
This Theorem is, perhaps, a somewhat surprising result.
Preface Can it be generalized? "multiplication by be eliminated?
xv
For example, can the hypothesis that
t:C
i
-+C
i
is injective, for all integers
. "
1,
Chapter 5, Theorem 4 answers this in the affir-
mative, if one assumes in addition that for the fixed integer
n, is finitely generated as left (A/tA)-module, where
0*
is the subcochain complex of
C*
such that
Also in Chapter 5, we introduce a new concept, "the percohomology groups of a cochain complex of left A-modules with coefficients in a right A-module,
M,"
which coincides with
is bdd. above and is flat
Hi (M
@
C*) if
C*
Hi (M,C*),
C* i E 'J'
A
over
A,
for all integers
invariant.
i,
but which in general is a new
Then, in the above theorem,
5), if we assume that the element
and if we replace
"Hn(C*/tC*)
tE A with
(Theorem 1 of Chapter is a non-zero divisor,
"H~(A/tA,C*)'" i
hypothesis that "mulitplication by t:c -+ c all integers
. "
1,
can be deleted.
i
then the
is injective, for
This is a somewhat finer
result than Theorem 1.
This is Chapter 5, Proposition 2.
( If the element
is not a non-zero divisor, then that
tE A
assumption can still be deleted if we replace with
"Hn{C*/tC*)"
"H;[T] {C*, .?'[T] / (T • .?' [T]) ) ") . As an application of the finiteness theorems of Chapter 5
(particularly Chapter 5, Theorem I), we prove, in the notations of [P.A.C.]'
xvi
Preface
Theorem AA.
Let
0
be an unramified(*), complete discrete
valuation ring of mixed characteristic, let and let
A = A ®l< (0).
-
0
Suppose that
A
A
be an O-algebra
is Noetherian.
Let
X
be a scheme simple and proper over
A
and embeddable over
(for this latter, it suffices that
X
be either quasiprojec-
tive over
A
Hh (X,~"),
h ~ 0,
"I\n,
or liftable over
see
[P.~C.l),
and let
be the lifted p-adic cohomology using the
as defined in
generated as
~,
A
[P.A.CII!].
Then
Hh (X,!2.")
~"-module, all integers
is finitely
h.
This is proved in Examples 1 and 2 at the end of Chapter 5.
In fact, it was in the course of proving Theorem A"
above
that we were led to prove the very general Chapter 5, Theorem 1,
(which will probably also have applications to other branches
of mathematics) . I also state Chapter 4, Theorem 6: Chapter 4, Theorem 6. let
tE A
Let
be any element.
A Let
be a ring with identity and C*
complex of left A-modules such that for all integers (1) (2)
n.
be any (~indexed) cochain n C is t-adically complete
Then for every integer
n,
Hn(C*)!(t-divisible elements) is t-adically complete. Hn(C*)
has no non-zero infinitely t-divisib1e e1e-
ments. (3)
[H n (C*)/(t-divisib1e e1ements)1~ Hn(C*)"t.
(3') For every integer
n,
we have an epimorphism from
(*)The hypothesis "unramified" can be replaced by the weaker condition "ord O (p) ~p - 1, where p is the characteristic of the residue class field of 0".
Preface
xvii
the group of equation (3) onto
lim [Hn(C*/tic*)].
i>O (4)
Also, for every integer
n,
there are induced
natural isomorphisms of abelian groups (or of left A-modules if
t
is in the center of
(t-divisible part of
A):
Hn(C*»~
liml(precise ti-torsion in
Hn(C*».
i>O (5)
Also, for every integer Hn(C*),
n,
the subgroup of
the t-divisible part of
Hn(C*),
is con-
tained in the subgroup liml Hn-l(C*/tic*)
i>O of
Hn(C*).
And Note 2 of Theorem 6 states, Note 2. If for any fixed integer
n,
we have that
Im(dn:C n ~ c n + l )
has no non-zero t-torsion elements, then for
that integer
the epimorphism of equation (3') is an iso-
n
morphism, and then also the two subgroups of
Hn(C*) discussed
in conclusion (5) coincide. A special case of Chapter 4, Theorem 6 is that in which (multiplication by gers
n.
t):
Cn~Cn
is injective, for all inte-
Then Note 2 above applies for all integers
n.
That
special case is Chapter 4, Theorem 1 and Theorem 1'. Under the more general hypotheses of Theorem 6, one might wonder whether one can obtain the stronger conclusions of Note 2 above, whether or not (multiplication by is injective.
n n t): C ~ C
The answer is "NO", as is shown in Remark 2
xviii
Preface
following Corollary 6.1 ("Example 2"). Theorem 6'
However in Chapter 4,
(in Remark 4 following Corollary 6.1), it is shown
that, if the hypotheses are as in Chapter 4, Theorem 6 and if in addition the element center of the ring
A,
tE A
is a non-zero divisor in the
and if we work with the appropriate
percohomology groups as in Chapter 5, then we obtain all the conclusions of Note 2, where in conclusion (3'), respectively: (5), we must replace
"Hn(C*/tic*)"
spectively:
"Hn-l(C*/tiC*)"
replace
ttH~(A/tiA,C*)'"
by
re-
"H~-l(A/tiA,C*)'"
by
(In Chapter 4, Remark 7 following Corollary 6.1, it is shown further that the hypotheses that and that
Itt
Itt
is in the center of
is a non-zero divisor"
the ring
A"
can be elimi-
nated if one uses the percohomology groups and
instead,
in conclusions (3') and (5) respectively.) Perhaps also relevant are Chapter 5, Corollaries 1.1 and 1.2.
In Chpater 5, Corollary 1.1, it is shown, e.g., that,
under the hypotheses of Chapter 5, Theorem I, we have that (l)
and
(2)
Does this result hold if we have the more general hypotheses of Chapter 5, Proposition 2?
(I.e., when we delete the hypo-
thesis that "multiplication by all integers
n"?)
t:C
n
-+
n C
is injective, for
The answer is "no", as is shown by an
example (Chapter 5, Remark 4 following Theorem 4).
(However,
if one uses the appropriate percohomology groups instead,
Preface
xix
then one obtains such generalizations, see Chapter 5, Corollaries 1.1' and 1.1".)
E~(ti)
Under the hypotheses of Chapter 5, Theorem 1, if
denotes the abutment of the Bockstein spectral sequence of the cochain complex plication by
C*
ti",
with respect to the endomorphism, "multias defined in Chapter 1, then in Chapter
5, Corollary 1.2, we show that for the fixed integer
n
of
Chapter 5, Theorem I, we have that (1)
[lj,m E~(ti) 1 ",Hn(C*)/(t-torsion), i>O
and
(2)
This Corollary generalizes, Corollary 1.2'
(respectively:
lary 1.2"), to the situation of Chapter 5, Theorem 6' tively:
Corol-
(respec-
Theorem 6), if the Bockstein spectral sequences are
defined suitably (in essentially the only way that is possible, see Chapter 1). Under the more general hypotheses of Chapter 4, Theorem 1, for all integers
and
(1)
[lj,m i>O
(2)
[lj,m i>O
n
we have that
E~(ti) 1'" Hn(C*)/(topological t-torsion), l
E~(ti)l'" ~iml (the kernel of the endomorphism 1>0
induced by "multiplication by {t-divisible elements in This is Chapter 4, Corollary 1.1.
ti"
on
Hn+l(C*)}). The
conclusio~of
Chapter
4, Corollary 1.1 hold equally well in the more general situation of the hypotheses of Chapter 4, Theorem 6, see Chapter 4,
xx
Preface
Remark 7 following Corollary 6.1.
(See also Chapter 4, Corol-
lary 1.1' in Remark 5 following Corollary 6.1.)
(Perhaps also
of interest is Chapter 4, Proposition 3, that under the hypotheses of Chapter 2, Corollary 1.2, if
n
is a fixed integer
such that
then
(Chapter 4, Remark 6 following Corollary 6.1, is also of some relevance to Chapter 4, Theorem 6.) A somewhat amusing set of side results in Chapter 4 are several lemmas and theorems that give information about tdivisible elements, etc., in left A-modules with identity
A,
where
t
is an element of
M
over a ring A.
These in-
clude Lemma 1.1.1 (which asserts that if "left mUltiplication by
t":
M-+M
is injective, then the same is true of
the t-adic completion of
M),
MAt,
Theorem 4, Proposition 5, Corol-
lary 5.1 and Corollary 5.2 of Chapter 4.
E.g., in Chapter 4,
Proposition 5, it is shown that if every t-divisible element of M
is infinitely t-divisible (e.g., this is the case if, either
M has no non-zero t-divisible elements (as for example if is t-adically complete), or if (left multiplication by M-+ M
t):
is inj ecti ve), then liml (kernel of the endomorphism, "multiplication by
i>O till,
of
M)
M
Preface
""
i~~
where
(kernel of the endomorphism, "multiplication by
"MAt/Mil
from
xxi t
i
,"
denotes the cokernel of the natural mapping
M into its t-adic completion
MAt
(whether or not that
mapping is injective). Chapters 1-5 constitute Part I of the book, and is the main emphasis of the book.
Part II consists of Chapters6 and 7.
In Chapters 6 and 7, we are concerned with the highest nonvanishing cohomology group, and with Poincare duality, respectively.
Some of the results are of particular use in applica-
tions to algebraic geometry, and in particular to p-adic cohomology (e.g., see [P.A.C.]), and also to more traditional resuI ts in algebraic topology, as we show in some examples. E.g., in Chapter 6, suppose that we have an integer
n,
such that Hi (C* /tC*)
=
0
for
i> n,
Then what can we say about i ::.. n)?
and such that
Hn(C*)
(and about
Hi(C*)
for
The most general such question is answered in Lemma 1.
The case in which
Hn(C*/tC*)
is finitely generated is covered
in Proposition 2.
The later theorems and propositions of Chap-
ter 6 deal with the case in which (A/tA)-module of rank one.
Hn(C*/tC*)
is a free
Chpater 6, Theorem 4, is particu-
larly useful in [P.A.C.]. In Chapter 7 we study Poincare duality.
The most notable
theorem is Theorem 3 and Corollary 3.1, which study the
xxii
Preface
problem: ring
A
is a differential graded algebra over the cmv.
C*
If
and i f
A
ci
and
are t-adically complete, for all
i, and i f the graded (A/tA)-algebra
integers
Hi (C*) ,
obeys Poincare duality over the quotient ring
i E 7/,
(A/tA), then
when can one conclude that the graded A-algebra, Hi(C*)/(topological t-torsion), obeys Poincare duality over the ring that:
iE7/, A?
Basically, one needs
Hn(C*)/(topological t-torsion) has annihilator ideal
zero; that
Hi(C*)
has no non-zero t-divisible, t-torsion ele-
ments, for all integers
i;
and that the ring
tive as left (A/tA)-module.
A/tA
The first two of these conditions
are reasonable, but the third is very restrictive. this latter condition holds in the case that valuation ring and lary 3.1).
t"F 0
is injec-
A
However,
is a discrete
(the resulting statement is Corol-
This result, and Chapter 6, Theorem 4, are used
to prove that: If
X
is a complete, non- singular (not necessarily lift-
able) embeddable ([P.A.C.]) algebraic variety over a field of characteristic
p,
and if
0
is an unramified, complete
discrete valuation ring of mixed characteristic having residue class field, then if
k
Hi(X,OA),
iE7/,
k
for
is the author's
lifted p-adic cohomology using the "A", as defined in [P.A.C.], then, for
Hi(X,OA)/(t-torsion),
duality over the ring
O.
iE7,
See [P.A.C.].
we have Poincare This is the principle
application of Chapter 7 to our general study of the Weil zeta function [W.C.].
{Chapter 6, Theorem 4 also has application
to algebraic families; i.e., in the notation of [P.A.C.], to
Preface X
over
A
simple, proper,
embeddable over
~).
xxiii
(not necessarily liftable), and
And of course there are more traditional
applications to algebraic topology. In Chapters 1-7, we have dealt with completions with respect to an ideal that is generated by a single element
t.
In
Part III, we make a study of the analogous situation, for completions with respect to finitely generated ideals that are not necessarily simply generated.
Part III consists entirely of
Chapter 8. In Chapter 8, we return to more fundamental considerations as in Chapters 4 and 5, but generalized as follows. a ring (not necessarily commutative) and let finitely generated two-sided ideal in I-adically complete.
Let
C* i C
of left A-modules such that integers
i.
be a
be
be a left
such that
~-indexed)
A
A
is
cochain complex
is I-adically complete for all
Then we state a generalization of Chapter 5, Theo-
(Chapter 8, Theorem 1.
rem 1.
A
I
Let
generated by an "r-sequ~nce for
The ideal i C ",
I
is required to be
all integers
i, see
Chapter 8, Definition 2.) If the ideal
I
admits a set of generators contained in
the center of the ring
A,
then one can state a generalization
of Chapter 5, Theorem 4, namely Chapter 8, Corollary 1.3. with identity and let A
I
Let
A
be a left Noetherian ring
be an ideal in the ring
A
such that
is I-adically complete; and such that we have an integer
r> 0 ideal
and a finite sequence I
tl, ... ,t
r
of generators of the
contained in the center of the ring
¢:7[Tl, .•. ,Trl
~A
A.
Let
be the homomorphism of rings with identity
xxiv
Preface
that sends
Ti
into
t
i
,
1 < i < r.
Let
C*
be a ':1'-indexed) c i is I-adically
cochain complex of left A-modules such that complete, all integers
i.
Let
[ ,···,T lilT 1' ... ' T) , Cj ) , l ,···,T r I(1'T D.lj = Tor.7.I'[T l r r l i, j E 1', (1)
i > O. H
n +i
for (2)
Let
(D~)
Hn(C*)
~
be any fixed integer.
Then if
is finitely generated as left (A/I)-module,
l
0
n
i
~
r,
then
is finitely generated as left A-module.
More general theorems are demonstrated, if merely
I
ad-
mits a finite set of generators that mutually commute, and a less restrictive set of hypotheses apply, assuming that one uses the percohomology~: "Hn(C*/IC*) ", sition 2.
"H~(A/I,C*)"
in lieu of
see Corollary 1.1 and Remark 2 following Propo-
Also, see Chapter 8, Corollaries 1.2 and 1.3'.
(As
a fairly straightforward application of the general theory developed in Chapter 8 to algebraic geometry, in Examples 1-4 of Chapter 8 we deduce by a new method almost all of the wellknown finiteness theorems about cohomology of coherent formal sheaves over proper formal schemes.) Theorem 6 and its Corollaries in Chapter 8 generalize Corollary 1.1 of Chapter 5. and the
liml
(They concern the inverse limit
of the "percohomology groups
mod In".)
results in Chapters 4 and 5 (particularly Chapter 5) generalized to the situation of Chapter 8.
Other are
E.g., Chapter 5,
Proposition 3 is so generalized, see Chapter 8, Proposition 4. Concerning the level of generality of the various chapters:
Preface
xxv
Most of Chapter 1 generalizes to virtually any abelian category, and this is proved.
Chapter 2 requires an abelian category such
that denumerable direct products exist, and such that denumerable direct product is an exact functor, see Introduction, Chapter I, section 7, and this generalization is noted in Remarks. Also, in Chapter I, only the cohomology sequence and not necessarily the cochains, is needed; and in Chapter 2, any cohomology theory,
(not necessarily the cohomology of cochain complexes)
will do.
Chapter 3 again requires an abelian category such
that denumerable direct products exist and such that the functor, "denumerable direct product" is exact,
(but now the coho-
mology theory must be the cohomology of cochain complexes).
The
same is true for all of Chapter 4, as is noted in the text But Chapter 5 requires that we be in the category of (7-indexed) cochain complexes of left A-modules, where that
tEA
tl\ CAt).
be in the center of
A
A
is a ring,
and
(or at least, be such that
Part of Chapter 6 is at the same level of generality
as Chapter 4; but the rest of Chapter 6, and Chapters 7 and 8, again require a ring
A
and the cohomology of cochain complexes.
In keeping with the general philosophy to make the material accessible to beginners, the main text of the book, Chapters 1-8, has been written for the most part at the level of generality of left modules over a ring, even when the more general situation of abelian categories was possible; and the generalizations to abelian categories have been kept in Remarks, that may be ignored by the reader who is not interested in, or cognizant with, these generalizations. Some of the results of this book are somewhat surprising.
xxvi
Preface
These include Chapter 5, Theorem 1; Chapter 4, Theoremsl and 6 and Corollary 6.1.
Perhaps also interesting are Chapter 4,
Proposition 5; Chapter 6, Theorem 4; and Chapter 7, Corollary 3.1; and the theorems of Chapter 8.
We give examples to show
that most of the pathology that would not be excluded by these theorems actually occurs - a very partial list is Chapter 4, Examples 1 and 2, and Example 2 in Remark 2 following Corollary 6.1: and Chapter 7, the Example following Theorem 3 (e.g., the latter example shows the difficulties in attempting to improve Chapter 7, Theorem 3). My special thanks to Mrs. Marion Lind and Mrs. Sandi Agostinelli for their excellent work in typing up this manuscript; and especially to Mrs. Sandi Agostinelli, for putting in so much overtime work, and more than usual care and patience.
Terminology. if
A
Ingeneral, we use conventional terminology.
is a ring and
tEA
and if
M
E.g.,
is a left A-module, then
°,
is t-divisible iff for every integer i > -i v. EM such that t • v. = u. The element u is
uEM
an element there exists
1
1
infinitely t-divisible iff there exists a sequence of elements of and such that v
M such that
°= u.
t · v + =v ' i l i
vi'
i> 0,
all integers
i.::O,
It is easy to give examples of t-di visible
elements that are not infinitely t-divisible. Similarly, if and if
t
M is a left A-module, where
is an element of
terminology, an element exists an integer element
u EM
i >
°
A,
uE M
A
is a ring,
then, following the usual is a t-torsion element iff there
such that
t
i
·u=O.
a precise t-torsion element iff
We will call an t · u = 0.
Thus,
Preface if
i> 1,
then an element
ment if and only if
uE M
t i . u = O.
xxvii
is a precise ti-torsion ele-
Thus,
"u
a precise t-torsion
element" implies "u a precise ti-torsion element" implies "u . a preclse
. t i+l -torslon e 1 ement " .lmp l'les
element", for all integers ti-torsion elements in
M
i > 1.
is the precise ti-torsion part of
(Thus, for each integer
of
M is the kernel of the endomorphism of the abelian group
is at-torsion
The set of all precise
M.
tin
"u
i::.l,
the precisE'! ti-torsion part "multiplication by
M).
However, we do deviate slightly from the most commonly accepted notational convention in our manner of indexing a bigraded exact couple.
E.g., what would be written as
in the original reference [E.C.], is denoted in this text as
That is, we have as usual emphasized the filtration degree
p,
but we have also chosen to emphasize the complimentary degree q
rather than the more traditionally emphasized total degree
n = p + q.
We believe that our indexing notation helps make
comprehension overall a bit easier, perhaps because of the even more rigidly entrenched indexing notational convention, "E~,q". The research for the main text of this book was done mostly at the Pennsylvania State University in 1973-74, except for virtually all of Chapter 2 which was done at the University of Oxford, England in 1963-64, and was partially supported by NSF Research Contracts, respectively an NSF Postdoctoral
xxviii Fellowship.
Preface An early version of this manuscript was pre-
pared in 1975, and is substantially the same as Chapters 1-7 of this ms., and contains the most important parts (Theorem 1 and its Corollaries) of Chapter 8.
Some extensive "touching up" of
Chapter 8 was done at the university of Rochester in the academic year 1977-78. The research for Introduction, Chapter 1, section 4, was done at Columbia College, in the academic year 1958-59, and was supported by a Pulitzer Scholarship and a New York State Regents Scholarship for Education in Engineering, Chemistry, Physics and Mathematics.
(The Exact Imbedding Theorem was
also proved, roughly simultaneously, by a somewhat different method, in [P.F.]).
Introduction, Chapter 1, section 5 was
done at the University of Rochester in Spring, 1979.
Intro-
duction, Chapter 2, sections 1-7, were mostly worked out at the University of California at Berkeley in the 1960's, and owe a debt to an early version of [O.A.L.l, and were partly supported by NSF grants. of Rochester in spring NSF grant.
They were written up at the University to fall, 1979, partly supported by an
Introduction, Chapter 2, sections 8-10 were com-
pleted at the University of Rochester in summer and fall, 1979, and were partially supported by an NSF grant.
TABLE OF CONTENTS
v
DEDICATION
vii
PREFACE INTRODUCTION Chapter 1
Manipulating in Abelian Categories
1
Categories
1
Section 1
Chapter 2
Section 2
Subobjects and Quotient-Objects
Section 3
Abelian Categories
4 11
Section 4
Imbedding of Abelian Categories
44
Section 5
Subquotients
56
Section 6
Left Coherent Rings
66
Section 7
Denumerable Direct Product and Denumerable Inverse Limit
80
Theory of Spectral Sequences Section 1 Section 2
Spectral Sequences in the Ungraded Case
97 97
The Spectral Sequence of an Exact Couple, Ungraded Case
111
Section 3
Graded Categories
137
Section 4
Spectral Sequences in a Graded Abelian Category
185
Section 5
The Spectral Sequence of an Exact Couple, Graded Case
208
Section 6
Filtered Objects
235
Section 7
The Partial Abutments of the Spectral Sequence of an Exact Couple
278
The Spectral Sequence of a Filtered Cochain Complex
339
Convergence
400
Section 8 Section 9
Section 10: Some Examples
441
PART I Chapter 1
The Generalized Bockstein Spectral Sequence
465
Chapter 2
The Short Exact Sequence 1.8
493
xxix
xxx Chapter 3 Chapter 4 Chapter 5
Table of Contents Cohomology of an Inverse Limit of Cochain Complexes
531
Cohomology of Cochain Complexes of t-Adically Complete Left A-Modules
539
Finite Generation of the Cohomology of Cochain Complexes of t-Adically Complete Left A-Modules
607
PART II Chapter 6
The Highest Non-Vanishing Cohomology Group
659
Chapter 7
Poincare Duality
687 PART III
Chapter 8
Finite Generation of the Cohomology of Cochain Complexes of I-Adically Complete Left A-Modules for a Finitely Generated Ideal I
BIBLIOGRAPHY
737 801
CHAPTER 1 MANIPULATING IN ABELIAN CATEGORIES Section 1 Categories
Most of the material of Parts I, II, and III of this book, is about cochain complexes of left modules over a ring.
It is
noted, in the various chapters, that some material generalizes to suitable abelian categories.
Therefore, we write this brief
introductory chapter to acquaint the reader unfamiliar with abelian categories with this important concept.
(The reader
who does not wish to learn about abelian categories can skip this chapter, and can read Introduction, Chapter 2 with "abelian groups" replacing "objects" throughout.) We will assume in this chapter that the reader is familiar with the concept of "category", and of the dual of a category, as defined in the original, still excellent, reference [C.A.]. We recall a few definitions from [C.A.], those of monomorphism and epimorphism. Defini tion. then and
=f
and 0
h,
A map f
C
is a category and
f: A -+ B
f is a monomorphism iff whenever g
fog
If
h
are any maps from
then f:A-+B
g
0
0 into
C,
is any object in A,
C,
such that
= h. in the category
C
is an epimorphism iff
is a monomorphism considered as a map from
the dual category
is a map in
B
into
A
in
Co.
Equivalently a map,
f:A -+ B 1
is an epimorphism iff given
Section 1
2
any object then
D
and maps
g,h:B
->-
D
such that
go f =h
0
f,
g = h. A map
f:A
B
->-
there exist a map
in the category g:B
-+
A
C
such that
is an isomorphism iff
gO f = idA
and
fog = id . B
A map that is an isomorphism is always both an epimorphism and a monomorphism, but the converse is in general false. Examples.
1.
If
C
is the category of sets and functions
(or
the category of groups and homomorphisms; or the category of abelian groups and homomorphisms; or the category of rings and homomorphisms; or the category of commutative rings and homomorphisms), then a map is
a monomorphism iff it is one-to-one,
and is an epimorphism iff it is onto.
In these cases, a map is
an isomorphism iff it is both an epimorphism and a monomorphism. 2.
If
C
is the category of all topological spaces
and continuous functions, then a map is a monomorphism iff it is one-to-one; an epimorphism iff it is onto; and an isomorphism iff it is a homeomorphism.
In this case, not every map that
is both an epimorphism and a monomorphism (i.e., that is oneto-one and onto) is an isomorphism (i.e., is a homeomorphism). 3.
If
C
is the category of all Hausdorff topo-
logical spaces and continuous functions, then let a map.
Then
f
is a monomorphism iff
is an epimorphism iff the is dense in IIf
Y
is onto").
f
f: X ->- Y
be
is one-to-one.
set-theoretic image
f(X)
of
f f
(this is in general weaker than the condition, f
is an isomorphism iff
f
is a homeomorphism.
Therefore in this category also, not every map that is both a monomorphism and an epimorphism is an isomorphism. We will also assume, in this chapter, that the reader is
Categories
3
familiar with the notions of the direct product and direct sum of an indexed family of objects in a category, as presented in [C.A.], and also with the definitions and elementary properties of the inverse limit (or direct limit) of an inverse (or direct) system in a category indexed by a directed set, as covered in [C.A.].
(This generalizes without change to the case in which
the indexing directed set is replaced by a directed class (i.e., a non-empty class (see [K.G.]), perhaps even a proper class, with a preorder such that for every x,y there exists a z such that
x:::. z,
y:::. z)
.)
Section 2 Subobjects and Quotient-Objects
Let
A
be a category and let
Then consider the class UK.G.]) B is an object in
A
and
MA
f:B -+ A
be an object in
A
(B',f')
and
(B",f")::. (B' ,f') category
A
is a monomorphism.
are elements of
f'
f' 0 g = f".
Let
Then we
M , A
that
g:B" -+B'
If such a map
in the g
exists,
is a monomorphism) it is unique; and (since
A
(B', f'),
where
by defining, when-
is a monomorphism) i t is a monomorphism.
Lemma 1. let
M , A
iff there exists a map
such that
then (since fll
(B",f")
(B, f)
of all pairs
have a natural pre-order on the class ever
A.
be a category, let
(B" , fll) E M . A
A
Therefore,
be an object in
A
and
Then the following two conditions
are equivalent.
1)
Both
2)
There exists an isomorphism
the category
(B' ,f')::. (B",f")
A,
such that
and
(B",f") 8
~
from
(B' ,f') B"
in
onto
M . A
B',
in
f' 0 8 = f ".
When these equivalent conditions hold, then the isomorphism of condition 2) is uniquely determined. Proof:
2)
=-
that
=-
f' 08 = fll,
(B",f") < (B',f'),
and therefore,
1)
We have
1)
2):
f'o8=f"
Let and
8 :B" -+ B' f"oT=f'. 4
respectively
respectively
and Then
T:B' -+ B" f'o8
o
f' = f" 08- 1 ,
(B',f') < (B",f"),
be maps such T=f"oT=f'=f' oid
B
Subobjects and Quotient-Objects whence since
f'
is a monomorphism,
Therefore follows since
f'
Definition 1.
Let
in
A.
8
M , A
= id ,
8T
Similarly
B
is an isomorphism.
Uniqueness of
is a monomorphism.
A
8
Q.E.D.
A be a category and let
Then a subobject of
pairs in
5
A
be an object
is an equivalence class of
where two pairs
and
(B' ,f')
(B",fll)
are
equivalent iff the two equivalent conditions of Lemma 1 hold. Given two sUbobjects there exist
S'
and
S"
of
(equivalently: for all)
(B",f")ES",
we have
A,
we say
(B' , f ') E S'
Given a category
mayor may not be a set) and an object
A
A,
in
strongest form of the Axiom of Choice (see [K.G.]) Mi
of
MA
~
sentative pair A,
A
(which
then by the (*)
,
there
We will call
a complete class of representatives for the
such a class
object
and
that contains exactly one repre-
sentative element from each equivalence class.
subobjects
iff
(B',f') 2. (B",f")
We next make a convention.
exists a subclass
S' < S"
It is a class containing exactly one reprefor each subobject
(B',f')
{(B' ,f')}
of the
and consisting only of such representative pairs.
Having chosen such a fixed complete class of representatives for the subobjects of A
A,
by a class (or set) of subobjects of
we will mean a subclass (or subset) of the complete set of
(*)In [K.G.], Godel proves that this strong form of the Axiom of Choice is consistent with the other, standard, axioms of his set theory, assuming that those other axioms are themselves consistent. (The statement of this strongest form of the Axiom of Choice is, that "There exists a well-ordering on the class of all sets".)
5ection 2
6
representatives M~
sentatives
M~.
Also, since the complete class of repre-
is a subclass of
M , A M'
pre-ordered class, we have that
(B', f')
(B", f")
and
5'
iff
and
5"
of
A,
if M'
(B',f') < (B",f")
5' < 5"
A
as subobjects of
in the complete class of representa-
M~.
tives
A and an object
It might be, given a category
that a complete classof representative;; M'
A
of
is a
are their unique representatives in
we have by Definition 1 above that A
MA
is a pre-ordered class.
A
In addition, given two subobjects
and since
A
is a set.
in
A,
for the subobjects
If this is so, then it is independent of the
choice of the class of representati ves the subobjects of cardinality of
A
M~
A
form a set.
M~,
and we say that
Also, in this case, the
is independent of the choice of the complete
M'
class of representatives
and we then call this cardinal
A
number the cardinality of the set of all subobjects of
A.
(The proof of these observations is that given any two complete classes of representatives A,
M'
and
A
for the subobjects of
then there is a unique bijection
from
M'
A
onto
M"A'
such that
S(B,f)
Remarks 1.
The reason for our introducing the notion of "a
is equivalent to
(B,f),
fora11
(B,F) in
complete class of representatives for the subobjects" is as follows.
In Godel's set theory,
[K.Gl, one cannot speak of a
class some of the elements of which are proper classes.
A
by Definition 1 above, if and
A
is an object in
A,
But,
is a category that is not a set, then it is possible for some, or
even all, of the subobjects of
A
to be proper classes.
(E.g. ,
Subobjects and Quotient-Objects
A is the
this is the case if if
A
and if
is any object in A
A;
ca~egory
7
of abelian groups and
A is the category of sets
or if
is any non-empty set).
Therefore, in Godel's set
theory, in such circumstances, one cannot speak literally of "a class, or set, of subobjects of
A"
in the literal sense of
Definition 1; so instead we speak of "a class, or set, of the representatives for the subobjects of
A", as in the above
convention. 2.
In the most common categories
A,
there is usually
a "natural choice" of a complete class of representatives for every object
A,
M'
A
making it unnecessary to invoke the
Axiom of Choice in that case. v·lhere not inconvenient, we will state results in
3.
such a way so as to not necessitate using the above convention (i.e., so as not to speak of "classes or sets of subobjects"). This is usually not di fficul t to do--al though some theorems become sloppy in their statement unless one uses the above convention, and then we will use the above convention. Examples. object
1.
A
A,
in
subobjects of a subset of
A is the category of sets, then for every
If
A A
a complete class of representatives for the is the set of all pairs
and
l:B ... A
A
where
B
is
is the inclusion.
Notice in this case that if every subobject of
(B,l)
A
is a non-empty set then
in the sense of Definition 1, except
for the empty subobject, is a proper class. this case, that the subobjects of
A
Notice also, in
form a set, and are in
natural one-to-one correspondence with the set of all subsets of
A.
8
Section 2
2.
A is the category of all groups (or abelian
If
groups, or rings, or commutative rings, or fields), then for every object
A
in
A,
representatives
M'
for the subobjects of
A
where
(B,l)
all pairs
as in Example 1, a complete set of
B
is
A
the set of
is a subgroup (or, respectively,
subgroup, or subring, or subring, or subfield) and the inclusion.
Again, the subobjects of
A
l:B
-+
A
is
form a set, in
natural one-to-one correspondence with the set of all subgroups (or,
resp~
subgroups, subrings, subrings, or subfieldsl of
3. and
A
If
A is the category of all topological spaces, A,
is an object in
tives for the subobjects of
then a complete set of representaA
is given by
{(B,l)}
where
is a topological space such that the underlying set of a subset of the underlying set of of B
A
AD'
Every pre-ordered class
such that the objects in
AD
B
B
is
and such that the topology
is finer than the induced topology from
4.
A.
0
A; and
1
is incl.
defines a category
are the elements of
0,
and such that {(a,en
Hom A (a,S) =
o
Let
0
!
a.:.B,
if
otherwise.
r,1
be the pre-ordered class of all ordinal numbers (as
defined in [K.G.]l with the reverse of the usual pre-ordering. Then for every object
A
in
AD
each Eubobject of
sists of a single element and is therefore a set. all subobjects of
A
e
con-
The class of
is a proper class, and is in natural one-
to-one correspondence with a <
A
{ordinal numbers
for the usual ordering}.
B
such that
Subobjects and Quotient-Objects Let
A be a category and let
A
9
A.
be an object in
Suppose that we have chosen a complete set of representatives for the subobjects of the object subobjects of
A,
A.
Then given a class
then by a supremum,or infimum, of
mean a supremum, or infimum, in the complete class
A.
tives
M
L
We write
B,
0
n B,
respectively
B{:S
S
S
of
we
f representa-
for this
B ES
supremum, respectively infimum, if it exists. A
For example, if remum of a set
H
is the category of sets, then the sup-
of subobjects of a set
A
is the usual
union, and the infimum is the usual intersection.
If
A is
the category of abelian groups, then the supremum of a set of subobjects of an abelian group
A
is their sum,
B= (B,
U
{finite sums of elements of
B};
H
l
)EH
and the infimum is
(B, l) EH
the set-theoretic intersection.
In the category of groups, the
supremum of a collection of subgroups of a group is the subgroup generated by the set-theoretic union; the infimum is the set-theoretic intersection. Definition 10. in
A.
Let
A be a category and let
Then a quotient-object of the object
A is a subobject of
A
(B',p'),
where
is an epimorphism; where
B'
p"=8
o
p'.
A
(B' ,p')
of representatives
AO •
A
E'
A
Thus, ex-
•
and
p':A->-B
is equivalent to
(B",p")
8:B' ->- B"
A
such that E'
A complete class of representatives
quotient-objects of
category
in the category O
A is an equivalence class of
is an object in
iff there exists an isomorphism
be an object
A
in the dual category
plici tly, a quotient-object of pairs
A
in the category
A
for the
--
A is a complete class
for the subobjects of
A
in the dual
This is in a natural way a pre-ordered class;
Section 2
10
we can speak of a class (or set) of guotient-objects of
A,
and of the supremum or infimum of such a class when the supremum or infimum exists. Examp 1es. 1 0.
In Example 1 above, a complete set of representa-
tives for the quotient-objects of a given set
A,
gory of sets
is the set of all pairs
the quotient-set of p:A -+ B
A
(B,p)
in the catewhere
B
is
by some equivalence relation, and where
is the natural mapping. 2
0
•
In Example 2 above, a complete set of reps. for
the quot.-objs. of a given obj. A in (B,p)
A
where
B
A is the set of all pairs
is a quotient-group (resp.:
group; a quotient ring; a quotient ring; natural map into the quotient (resp.:
30
•
A)
a quotient and
p
ibid, ibid, ibid,
In Example 3 above, a complete set of representa-
tives for the quotient-objects of a topological space the pairs
is the
(Y,p)
where the underlying set of
quotient-set of the underlying set of relation, and where the topology of quotient topology; and where
p: X -+ Y
X Y
Y
X
are
is the
for some equivalence
is coarser than the
is the natural mapping.
Section 3 Abelian Categories
Definition 1.
A pointed category is a category
e,
together
with the additional data, the giving, for every pair objects of (Zl)
e,
A,B
of
of
A map,
0A,B
from
A
into
B
in the category
e,
such that (Z2)
For every object
in
e
e
e
g:B+D,
respectively
g oOA,B =OA,D e,
the maps
for all objects
and every map f:D+A,
we have that
are called the points.
0A, A E Home (A, A) , If
in
respectively
Given a pointed category A,B
D
0A,B
0A,B of=OD,B'
for all objects
We often write
0A
for
A.
is a category that admits the structure of pointed
category, then the points are uniquely determined by the category structure of Proof: in
e
In fact,
e. if we had another set of points
obeying axioms (Zl)
and
(Z2)
(0'A,B ) A,B objs.
above, then using
(Z2) ,
°A,B--0 A,B for all objects
00'
-0'
A,A-
A,B
in
A,B'
A.
Q.E.D. 11
Section 3
12 Examples 1. set and
A pointed set is a pair (S,so)
So E S.
S
is a
Then we have the category of pointed sets,
such that for all pointed sets (S,so) -.. (T,t ) o
where
(S,so)
are all functions
f
(T,t )' the maps: o
and S
from
into
T
such
The category of pointed sets is a pointed category. 2.
The category of groups and homomorphisms is a
pointed category. 3.
The category of abelian groups and homomorphisms
is a pointed category. 4.
The category of sets and functions is not a pointed
category (since, e.g., 5.
Hom{sets} (S,<jl) = <jl).
The category of non-empty sets and functions is
not a pointed category. 6.
(Proof left as an exercise) .
The category of rings (or of commutative rings)
with identity and homomorphisms of rings (that preserve the identity element) is not a pointed category. Hom( {oJ ,if) = ».
(Since e.g.,
Similarly for the category of all non-zero
rings (or of all non-zero commutative rings) and such homomorphisms. Definition 2.
An additive category is a pair
(C , (+ A,B ) A,B objects in
) C'
where
where, for every pair of objects nary composition on the set (ADl) +A,B
HomC(A,B)
C
A,B
is a category, and of
C,
+A,B
HomC(A,B), such that
together with the binary composition
is an additive abelian group, and (AD2)
Whenever
is a bi-
A,B,D
are objects in
C
and
Abelian Categories
13
have that k O(f + g) = k
g
in
Home (A, D)
(f+g) oh=foh+goh
in
Home(D,B).
0
f +k
0
,e,
Given a category
a doubly indexed system that obeys axioms (ADI) and (AD2) ,
e
(+A,B) A.B cbjects in
and
will be called an additive structure on the category
e.
As we shall see in the next Remark, every additive category is pointed; but the converse is in general false (vide infra) . Remarks l .
Let
objects of
e.
be an additive category, and let
e Let
(respectively:
k EHome(B,D)
be
let
Then the first part (respectively:
hE Home(D,A».
A,B,D
second
part) of axiom (AD2) is equivalent to the assertion that the function:
f
+
k .Of
(respectively:
of abelian groups from tively:
into
Home(A,B)
Home(D,B».
f
f oh)
+
into
Home (A,D)
Therefore, if
0A,B
zero element of the additive abelian group objects (1)
whenever (2) whenever
A,B
in
e,
k E HOme (B, D) ,
0
respectively: resp.:
(f-g) =k of-k og,
f, g E Home (A, B),
Equations (1)
(respec-
denotes the
Home(A,B)
for all
then we have that
k oOA,B = 0A,D'
k
is a homomorphism
0A,B Oh=OD,B'
hEHome(D,A), and
and
(f-g) oh=f oh-g oh,
k E Home (B, D)
and
hE Home (D, A) •
imply that every additive category has a
natural structure as pointed category, by taking the additive identity element of objects
A,B
in
A.
HomA(A,B)
for the point
0A,B'
for all
14
Section 3
Remark 2.
suppose, in the definition of "additive category"
above, we weakened axiom (ADl) , by saying instead that (ADl')
HomC(A,B) +A,B
together with the binary composition
is an additive group (that is not necessarily
abelian) . Then we claim that axiom (ADI'), in the presence of axiom (AD2) , is equivalent to axiom (ADl). Proof:
Suppose we have axioms (ADl') and (AD2).
any objects
A,B
f,g€HomC(A,B)'
in the category
C
Then given
and any two maps
by axiom (AD2) and the associative law, we
have that (Hg)
o
idA + (f+g)
0
idA =f+g+£+g.
On the other hand,
Therefore f+g+f+g Since
f+f+g+g
Home (A,B)
in
P.omC(A,B).
is a group, by the left and right cancella-
tion laws we have f+g=g+f. ~xample
call it
7. P,
Let
e
be the category consisting of one object,
and such that
monoid of the ring 7. Home(P,p) =7.
Q.E.D.
Home(P,p)
of integers).
= (the
multiplicative
(This means that
as set, and the composition is given by multiplica-
Abelian Categories tion of integers).
15
Then there exists an additive structure on
C as in Definition 2 above, such that
the category
comes an additive category. "+" of integers.
C be-
Namely, take the usual addition
However, there are actually
additive structures on the category
C
lot
2
different
0
such that
C becomes
an additive category. Proof:
In fact,
if
is any permutation of the set of
IT
rational primes, then by unique factorization there exists a unique automorphism such that
a
IT
(p) =
two integers
IT
n,m,
a IT
of the multiplicative monoid
(p) ,
for all positive primes
"t"
usual multiplication, makes
P into a ring.
"+" IT
'
makes
additive structures
Given
define
Then the binary composition
datum,
p.
( lI, .)
C
lI,
into an additive
"+"
on the category
IT
different permutations
on
IT
together with the Therefore, the
ca~egory;
and the
C are distinct for
of the set of all rational primes. Q.E.D.
Example 7 above shows that, unlike a pointed category, an additive category cannot in general be thought of as being a category that obeys a certain set of axioms; but the additive structure must, in general, be thought of as a
new set of data.
However, we will see in Corollary 1.1 below, that unlike the situation in Example 7 above, for a wide class of categories, there is at most one additive structure.
First, we prove a
Proposition, that is quite important in its own right. Proposition 1.
Let
A be an additive category, let
n
be a
Section 3
16
non-negative integer and let
AI' .•• ,A
n
A.
be objects in
Then (A) maps
If there exists an object
71 i
:S'" Ai
and
(1)
71.
S
1.
OA' ,1\. J 1.
_
01.-
together with
such that
:A. + S,
1. 1.
A,
in
if
i'/-j,
if
i=j,
J
l
{ idA. 1.
1 ~i,j ,::,n,
and (2)
then the data
(S,7I , .•. ,7I ) l n
in the category [C.A.]),
1.:A. +S, l
(S,ll' •.• 'In'
Conversely, if n
l
(cl Al, ••• ,A
7Ii:S+Ai,
A , ... ,A l n
A,
in the category l,::,i,::,n,
is a direct sum of
(S,7I , ••• ,7I ) n l
is a direct product of
then there exist unique maps
such that equation:; (1) and (21 above hold.
Similarly, if n
of
(in the category-theoretic sense, see
and the data
(B)
Al, ... ,A
A
is a direct product
(S,ll, •.. ,ln)
A,
in the category l~is.n,
is a direct sum of
then there exist unique mappings
such that equations (II and (2) above
hold. proof:
Let
(A)=>(B) :
be any object and let
B
n
+
1
f
n n
)
L 7I.1.f.=
j =1
n
L 6 .. f j
j=l
Jl
=f., l
l,::,i,::,n,
l
J J
f. :B l
+
A. l
Abelian Categories
l
OA. ,A.
0 .. =
where
J1
J
~
~
i ,j
n;
i;ij,
if
i=j,
1
idA.
1
if
17
1
tha t i s
f = 11 fl + .•. + 1 f n n
Therefore
a direct product.
satisfies the existence part for
e
Conversely, if
'IIi 06=f
is any map such that
,
i
then 6
= ids
0
6
=
(1 I'll 1 + ... + 1 n 'II n)
11fl + •.• + 1 n f n
0
e = 1 1 ('II 1 e)
+ ... + 1 n ('II n e )
= f,
e=f.
(4)
Equation (4) is the condition of universality. (B)
=!>
(A):
For each integer
(S,'TT , ..• ,'TT ) 1 n
1 i :A ... S i
o J
1
is a direct product of
a unique mapping
A. ,A. 1 J
=
'11.01
i,
,
~
i
~
n,
since
A , ... ,A , l n
there exists
such that
j ;i i,
1
{ idA.
j = i,
1
But then, 1
'11
1 1
'TT
j
(1
'11
1 1
+ ••• + 1n'TTn) = 'TT j ,
+ •.. + 1n'TTn = identity of The proofs that
or can be deduced from
(A)~
1
~
j
~
n,
and therefore
S. (C)
and
~
(B)"
"(A)
(C)~
and
spectively by passing to the dual category.
(A)
"(B)
are similar-=!>
(A)"
re-
Q.E.D.
Section 3
18
Notice that the above Proposition implies that, in an
A,
additive category
if the direct product of finitely many
.objects exists, then so does the direct sum, and they are canonically isomorphic.
Also, conditions (1) and (2) of part
(A) give a way of defining the direct product (equivalently, the direct sum) of finitely many objects in an additive category, in a way not mentioning universal mapping properties. Both of these observations are special to additive categories. Corollary 1.1. every object of
A
Let A
in
with itself.
A be an additive A,
there exists a direct product
category
A
x
A
Then there exists at most one additive
A.
structure on that category Proof:
category such that, for
Suppose that there exists an additive structure on the
A.
If
A
A,
is an object in
be a direct product of
A
then let
(A x A.1T ,1T ) l 2 Then by Proposition 1,
with itself.
: A + A x A such that condi2 tions (1) and (2) of part (A) of Proposition 1 hold. But, since
part (B), we have unique maps
1
1
,
1
is a direct product of
A
with itself, by the
universal mapping property, condition (1) alone determines the mappings
1
1 ,1 2 ,
Since the point
0A=OA,A
depends only on the
category structure, it follows that the mappings depend only on the category structure. tion, part (A), we have that A
with itself.
(A x A,
Let
be the unique mapping such that
1
1
and
Then, by the Proposi,1
2
)
is a direct sum of
Abelian Categories
Then
depends only on the category structure of
direct sum of
If now A,
19
B
A.
But
A with itself, it follows th.at
is any (possibly different) object irt the category
and if
f,g:B->-A
are maps, then let
(f,g):B ->-A x A be the unique map such that
7Tl ° (f,g) =f,7T
0 (f,g) =g. Then 2 depends only on the category structure of A. And by
(f,g)
equation (3) we have that,
(4)
f+g=PA
o
(f,g).
Since the right side of equation (4) depends only on the category structure, it follows from equation (4) that the additive structure of
A
is uniquely determined by the category Q.E.D.
structure. Remark:
Of course, applying Corollary 1.1 to the dual cate-
gory, it follows,
likewise, that:
that, for every object A
A
in
A,
If
A
is any category such
the direct sum:
Ae A
of
with itself exists, then there is at most one additive
structure on the category
A;
i.e., that there is at most one
Section 3
20
A into an additive category.
way of making Let
C
be an arbitrary pointed category.
set, and suppose that category
(Ai)iEI
Let
I
be a
is a family of objects in the
A indexed by the set
I.
Suppose that the direct
sum, 6l A.
iEI ]. and the direct product, IT A. iU ]. of the objects
8:
Ai'
6l A. -+
iO].
all
i E L
where
i E I,
exist.
Then we define the canonical
IT A. iO].
if
i-lj,
if
i=j,
71.: IT A. -+A. , 1. j EI J 1.
the canonical projections, resp.:
resp.:
1.:A. -+
Ell A., jEI J injections, all i E I. ].
are
1.
Then Corollary 1.2.
If
finite set and if
A
is an additive category, if
Ai'
direct sum
i E I,
6l A. or the direct product iEI 1. they both exist, and the natural mapping
8: 6l A. -+
iEI
1.
IT A. i EI 1.
A
are objects in IT A. i EI
l.
I
is a
such that the exists, then
Abelian Categories
21
is an isomorphism. Proof:
By proposition 1, the indicated direct sum and direct
product both exist.
Let
(S 'TIl' ... ,TIn,ll' ... ,In)
part (A) of Proposition 1. of
e,
we have
e
=
be as in
Then by the defining property (3) which is indeed an isomorphism.
ids'
Q.E.D. Remarks 1. set, and
A
If
is an additive category,
i E: I,
A.
1
are objects in
A,
I
is an infinite
such that the direct
Gl A. and the direct product both exist, then the IT A. 1 iEI iEI 1 natural map e is in general neither a monomorphism nor an sum
epimorphism.
(In the category of abelian
groups it is of
course always a monomorphism.) 2.
Corollary 1.2 essentially characterizes all addi-
tive categories such that, for every object product:
AxA
exists.
Corollary 1.3. every obj ect Then
A (1)
Let A
A
inA,
A,
the direct
More precisely, be a pointed category such that, the di rect product
Ax A
for
exi s ts .
admits an additive structure iff For every object
A
in
A
the direct sum
AGlA
exists, and (2 )
For
every object
A
in
A,
the natural map
e:AGlA-+AxA is an isomorphism. Proof:
(We only sketch the proof, since we will make no use
of this elsewhere.)
Necessity follows from Corollary 1.2.
Conversely, suppose that conditions (1) and (2) hold.
Then
Section 3
22 for any object
A
follows that if
A,
in
since
jl,j2:A+A61A
and if we define
8
is an isomorphism, it
are the canonical injections,
11 =8 ojl,12=8 oj2'
a direct sum of
A
then
(AXA,11,12)
A.
with itself in the category
there exists a unique map in the category
is
Therefore
A,
PA:AXA+A, such that
If now from
B
is any other object in into
B
product of
A,
A
then since
A,
and
f
(A x A, 'TT l' 'TT 2)
and
g
are maps
is a direct
with itself, there exists a unique mapping
(f,g):B+AXA 'TTl ° (f,g) = f,
such that
'TT
2
° (£,g) = g.
Define f+g=PAo(£,g). Then we leave it as an exercise for the reader to verify that, for this definition of
A
that indeed Examples:
A,B
for all objects
in
becomes an additive category.
A, Q.E.D.
Example 1 above, the category of pointed sets, is
not an additive category:
Since if
(s,s) o
and
(T,t) 0
are
pointed sets, then the direct sum is "the disjoint union of and
T
with
(T x {U)I "',
So
glued to
where
to"
(s,O) '" (t,l)
(--Le., is iff
s = So
(SX{O})u and
t = to'
S
Abelian Categories all
s E S,
t E T);
23
and since the direct product (SxT,(s ,t », o 0
Cartesian product
is the usual
and the natural mapping is the "inclusion of the axes
into the product"
(i.e., is the function such that
8(t) = (s ,t), o
all
sES,
tET);
8(s) =
and although this
function is a monomorphism, it is not an epimorphism, either
card(S) or
card(T)
is one.
Example 2 above, the category of groups,
G
additive, since if the free product
G
and
*H
Cartesian product:
G
unless
H
is likewise not
are groups, the direct sum is
and the direct product is the usual
x H.
In this case, the natural mapping
G
is an epimorphism, but is not an isomorphism unless either or
H
8
is the trivial group (i.e., is of cardinality one).
Example 3 above, the category of abelian groups, is an additive category, if for groups, one defines
f,gEHomC(A,B),
f+gEHomC(A,B),
(f + g) (x) = f(x) + g(x),
all
A,B
abelian
by requiring that
x (;A.
Examples 4,5 and 6 above are not additive categories, since they are not even pointed categories. Remark:
If
A
is a pointed (respectively:
additive) cate-
gory, then it is obvious that the dual category is also pointed (respectively: to
B
in
AO
is defined to be
if the category
~A,B
on
Horn
additive); where the point
AO
A (A,B)
0B,A
from
in the category
A
in-
A;
is additive, then the binary composition ('" HomA(B,A»
in
is defined to be
and
Section 3
24
the composition
+B,A
additive category Defini tion 3.
where
K
HomA(B,A),
in the
A.
Let
C.
be a map in
on the abelian group
be a pointed category, and let
C
Then by a kernel of
is an object in
and
C
f
f:A -+ B
we mean a pair is a map in
l:K-+A
(K,l)
C
such that (1)
f
(2)
If
0
1
and such that
= OK, B
is any such pair(*),
(H, j)
then there exists a unique map
j
o
:H-+K
is commutative--that is, such that If
f:A -+ B
cokernel of
f
of
f
CO
is a pair
IT:B-+C
from (C,IT)
is a map in
C,
° ,
(1)
IT of = A,C
(2)
If
a unique map
(H,j) j
o
=1
0
jo'
is a map in the pointed category is a kernel of
dual category
j
such that the diagram:
:C-+H
B
f
iLto
where
considered as a map in the A.
C
then a
C,
Equivalently, a cokernel
is an object in
C
and
such that and such that
is any other such pair, then there exists such that the diagram:
(*)that is, if H is any object in a map such that f 0 j = 0H,B '
C
and if
j:H-+A
is
Abelian Categories
is commutative--that is, Proposi tion 2. be a map in (A.)
Let
C.
Let
such that
jo
0
25
IT
= j.
be a pointed category and let
C
f:A
-+
B
Then be an object and l:K
K
category
C.
(a) (K, l)
is a kernel of
-+
A
be a map in the
Then if and only if the fol-
f,
lowing three conditions all hold: (A.O)
f
= 0
1
0
K,B
is a monomorphism, and
(A.I)
(A.2)
Given any pair in f
C
and
j:H
-+
A
where
H
is a map in
is an object such that
C
th(re exists a map
j = 0H, B '
0
(H,j),
j
o
:H
-+
K
such that (B.)
Let
C
be an object and let
category
C.
(S)
is a cokernel of
(C,IT)
IT:B
-+
C
be a map in the
Then f,
if and only if the fol-
lowing three conditions hold:
= 0A,C '
(B.O)
IT
(B.I)
IT
(B.2)
Given any pair
f
0
is an epimorphism, and
in
C
and
j:B
Proof:
j0
0
IT
-+
H
where
H
is a map in
there exists a map
j of=OA,H ' tha t
(H,j)
is an object C j
such that o
:C'" H
such
=j .
Assume condition (a).
Then conditions (A.O) and (A.2)
Section 3
26
follow by Definition 3. ject and
Then
OK, B 0 h = 00, B.
j:D->A
0
be an ob-
1 0 h=l ok.
be maps such that
h,k:D~K
j=1 0 h=1 0 k.
On the other hand, let
is a map, and
Let
foj=f 01 oh=
By the universal mapping property, condition
(2) of Definition 3, we therefore have that there exists a unique map
j
:0
o
~
K
such that
obey this condition.
But both
Therefore
h = k.
This proves
Conversely, suppose that conditions (A. 0), all hold. H
Then by (A.O), we have that
is any object and
j:H
~
A
Suppose that Then
j~
j~,
1 0 jo = 1
this implies
is another such map, i.e.
I
and since by (A.l)
j 0 = j ~.
And, if
f oj = °H, B , 1 ojo=j·
that
1
oj~=j.
is a monomorphism,
Therefore there is a unique map
in condition (2) of Definition 3.
(A.l) and (A.2),
by passing to the dual categoLY.
be a map. (A.)
C
as
0
(B.l), and (B.2), fol-
lows from the equivalence of (a) with (A.O),
Let
j
This proves (4).
The equivalence of (S) with (B.O),
Corollary 2.1.
k
(A.!) and (A.2)
such that
jo
and
(A.2).
f 01 = 0K,B.
any map such that
then by (A.2) there exists a map
h
Q.E.D.
be a pOinted category and let
f:A
~
B
Then If a kernel
(K,l)
all kernels of
f
of
f
exists, then the class of
is a subobject of
A
in the sense
of section 2, Definition 1. (B.)
If a cokernel
(C,n)
of all cokernels of
of f
f
exists, then the class
is a quotient-object of
B
in the sense of section 2, Definition 1°. Proof: and
Suppose that a kernel of
(K',l')
are both kernels of
f
exists. f,
Then if
(K,l)
then by Proposition 2,
Abelian Categories (A.l) , we have that 2,
(K,
(A.O), applied to
And since
(K,l)
and
1 )
(K',
(K',l'),
1 ') E;
M . A
f,
l' o
(K',
1 ,)
.s.
(K,
such that
ment using that
(K',l ')
larly that
.s.
(K, l)
equivalent to
M . A
in
in
MA .
M , A
ThereMA
(see section 2),
Applying the same argu-
is a kernel of
(K' ,l ,)
(K',l ')
in
1 )
f ol' =OK',B
by condition (A.2) we
fore, by definition of the pre-ordering on we have that
By Proposition
we have that
is a kernel of
have that there exists a map
27
f,
we obtain simi-
Therefore
is
(K,l)
i.e., lie in the same sub-
object. Conversely, if and
(K,l)
(K' ,
1 ' ) 'V
(K,l)
is a kernel of
lie in the same subobject of
(K, l),
f, A,
and if i.e.
(K',l ')
if
I
then by section 2, Lemma 1, we have that there
exists a unique isomorphism
e:K' ~ K
therefore clearly by Definition 3 f.
Therefore the set of kernels of
of
A,
such that
(K',l ,) f
lo e =
1 '.
And
is also a kernel of
are an entire subobject
as asserted.
The latter part of Corollary 2.1 follows from the former Q.E.D.
part by passing to the dual category. I f now
in
C,
C
then we define the kernel of
be the class of exists.
all kernels
(K, l)
f, of
And we define the cokernel of
be the class of all cokernels f
exists.
f:A .... B
is a pointed category, and
(C,n)
f, of
Ker f ,
denoted f,
kernel of
f
object of
B.
Ker f,
is a subobject of
exists, then the cokernel,
Cok f,
denoted f,
to
i f a kernel of
f to
i f a cokernel of
Then, by Corollary 2.1. i f a kernel of
then the kernel,
is a map
A;
Cok f,
f
exists,
and if a cois a quotient:-
Section 3
28 Proposition 3. an object in
Let C.
C
be a pointed category and let
Z
be
Then the following eight conditions are equiva-
lent. (1)
OZ. Z '" id Z
in
(2)
Home(Z.Z)
has cardinality one.
( 3)
Home(Z.A)
has cardinality one. for all objects
A
has cardinality one. for all objects
A
in (4)
A.
HomC(A.Z) in
Hom (Z. Z) . C
A.
(5)
Z
is the direct sum of the empty set of objects.
(6)
Z
is the direct product of the empty set of objects.
(7)
There exists (equivalently:
A.
there exists a map
a kernel of (8)
idA:A
In condition (7) idA:A-+A
range)
(3)~(2)~(1).
has cardinality
have that
Horne (Z, A) f
0.
in
(Z. l)
objects
such that
is
A
(Z.71)
in is
(8)) one can replace the
A
5-1.
epimorphism)
A. Suppose (1).
and
Since
Therefore
Then if
f. g E Horne (Z. A),
= f 00 Z.Z '" 0 Z.A = g 0 OZ. Z '" g 0 id z = g.
HomC(Z.A)
(3).
71:A-+Z.
(respectively:
any obj ect in the category Z
For all)
with any monomorphism (respectively:
Obviously
f = f 0 id
that
A
idA:A-+A.
with domain (respectively: Proof:
such
objects
A.
there exists a map
a cokernel of
map
"* A.
There exists (equivalently:
A.
Note:
->
l: Z
For all)
A
is
'then
Therefore
0Z,AEHome(Z,A),
card Horne (Z, A) = 1,
we proving
Passing to the dual category, we see likewise that
(4)~(2)~(I)~{4).
We leave it as an easy exercise to the
reader to prove the equivalence of the remaining conditions and
Abelian Categories
29
(1), (2), (3) and (4).
Z
An object
Q.E.D.
in a pointed category
C
that obeys the
eight equivalent conditions of Proposition 3 will be called a zero object.
It is immediate that,
if a zero object exists,
then it is unique up to a unique isomorphism. symbol
0
Remarks: C,
We shall use the
to stand for the zero object. 1.
If a zero object exists in the pointed category
then every object
A
has a smallest subobject--namely, the
equivalence class of the element is any zero object in object of
A
objects in
We shall denote this smallest sub-
In a pointed category C,
C,
if
A
and
Bare
then when there is no danger of confusion, we 0A,B~
shall denote the point 3.
If
C
HomC(A,B)
O.
simply as
is a pointed category that does not have
a zero object, then we can "adjoin a zero object to wish.
Namely, let
category
C.
Z
be such that
Then define
C'
objects all the objects of object
Z.
Z
O.
by
2.
C.
where
C
Z
C"
if we
is not an object of the
to be the category, having for together with the one additional
Then define
HOmc(A,B), if A and B Hom ' (A, B) = { C (a set of cardinality one),
are objects of C, if
A
or
B = Z.
Then there exists a unique way of determining a composition such that gory.
C'
becomes a category and such that
And
C'
is a sub-cate-
is a pointed category with a zero object.
We do not, however, 4.
C
Let
C
insist on making this construction.
be a category (not necessarily pointed),
30
Section 3
and let
Z
be an object in
C.
Then condition (3) of Proposi-
tion 3 is equivalent to condition (5). equivalent conditions, then the category
C.
Z
If
Z
obeys these
is called a left zero object in
Passing to the dual category, we have like-
wise that conditions (4) and (6) of Proposition 3 are equivalent.
Z
is called a right zero object if it obeys these two
equivalent conditions. 5.
Let
C
be an arbitrary category.
Then the fol-
lowing three conditions are equivalent.
(1)
There exists an object
Z
in
C
that is
both a left zero object and a right zero object. There exists a left zero object
(2)
and a right zero object
ZR
in
C,
and
in
HomC(ZR'ZL)
C
is non-
empty. (3) zero object in that
There exists a right zero object and a left
C,
HomC(A,B)
and for all objects
A,B
in
C,
we have
t 0.
(4)
The category
C
is pointed, and there exists
a zero object. 6. gory
C,
gory
C
Example:
By Remark 5 above, if
then
Z
Z
is an object in a cate-
obeys condition (1) of Remark 5 iff the cate-
is pointed and
Z
is a zero object.
The category of sets has a left zero object (the empty
set) and a right zero object (any set of cardinality one) . Therefore, by Remark 5 above, the category of sets does not have a zero object.
More strongly,
by Proposition 3, it fol-
lows that the category of sets is not pointed (a fact that's obvious anyway).
Similarly, the category of non-empty sets
Abelian Categories
31
has a right zero object (namely, any set of cardinality one), but does not have a left zero object.
Again, by Proposition 3,
it follows that the category of non-empty sets is not pointed (a fact that is also obvious) . Corollary 3.1.
Let
C
a map in the category If
(A.)
f
be a pointed category. C.
is a monomorphism then
phism iff
Ker f
Ker f
exists iff a
C
is additive, and if
exists, then
f
is a monomor-
Ker f = 0.
(A.)
Proof:
be
Ker f = 0.
Conversely, if the category
either a zero object or
f: A -+ B
Then
zero object exists, in which case (B.)
Let
If
f
is a monomorphism and if a zero object
exists then one verifies using Definition 3 that a kernel of
f.
exists then
Z
(Z,OZ,A)
(z,d
On the other hand if a kernel
Z
of
is f
obeys condition (7) of Proposition 3, as modi-
fied in the Note to Proposition 3, and is therefore a zero object. (B.) f
Suppose that the category
be a map in
with
Z
C
such that a kernel
a zero object.
In fact, maps such that
let
D
To show that
be an object in
f ° h = f ok.
Then
C
is additive and let
(z,d
of
f
exists
f
is a monomorphism.
C
and
h,k:D-+A
be
f ° (h - k) = f ° h - f ° k = 0,
so that by the universal mapping property of Definition 3 there exists a map
t:D-+Z
a zero object, both h - k
= lot
Remark.
such that and
t
h-k=l °t.
But since
Z
is
are zero maps, and therefore
is a zero map, and therefore
h
= k.
Q.E.D.
Part (B.) of Corollary 3.1 does hold for some pointed
32
Section 3
categories that are not additive (e.g., the category of groups), but fails to hold for some pointed categories that are not additive. Example. (8,so)
If
is the category of pointed sets, then let 8
be any pointed set with
T={O,l} that
C
and let
f (s ) = t o
0
to={O}.
,
f (x)
of pointed sets, Definition 4. be a map in
= 1,
Let
Let C.
C
f: S
all
Ker f = 0,
of cardinality.:: 3, T
~
be the function such
xE;S-{s}. o
and yet
f
f
Then
f
is a map
is not a monomorphism.
be a pointed category and let (C,n)
Suppose that a cokernel
Then an image of
(I,k)
is a kernel
let
of
of
n.
f:A~B
f
exists.
Then by Corol-
lary 2.1, part (A.), and by section 2, the dual of Lemma I, if (C',n')
is another cokernel of
isomorphism
6
such that
(C.n)
of
f"
f
sufficient that a cokernel
kernel of
n
It follows readily that the
is independent of the choice of
f.
Thus. for an image of
some (equivalently:
then there exists a unique
n' = en.
definition of "an image of a cokernel
f.
all)
to exist,
(C,n)
of
it is necessary and
f
exist. and that for
(C,n)
cokernels
of
f.
that a
exist.
A co-image of
f
is an image of
in the dual category from
B
into
A.
f
considered as a map Using methods similar
to that of the proof of Corollary 2.1, we see that Proposition 4.
If
f:A .... B
if an image (respectively: the class of all images a subobject of
is a map in a pointed category, and a co-image) of
(respectively:
B (respectively:
f
exists. then
co-images) of
quotien~object
of
the sense of section 2. Definition 1 (respectively:
f A)
forms in
section 2,
Abelian Categories Definition 1
0
33
) •
The proof is elementary and is left as an exercise for the reader. If
is a pointed category and
C
C,
category
f:A
~
B
and if an image (respectively:
exists, then by the image (respectively: denoted
1m (f)
ject of
B
(respectively:
(respectively:
is a map in the co-image) of
the co-image) of
Coim(f»,
f,
we mean the subob-
the quotient-object of
ting of the class of all images (respectively: of
f
A)
consis-
all coimages)
in the sense of Definition 4 above.
f
We now make the conventions made in section 2, just after Definitions 1 and 10.
C, fix a com-
I.e., for every obj. A in
plete class of reps. for the subobjects of A, and also fix a complete class of reps. for the quotient-objects of Therefore, in particular, i f f : A ~ B such that
Ker f
(respectively:
Cok f.
Cok f.
(C, n),
Im(f), Coim f).
( I , k),
1m f.
We often call
the kernel (respectively: of
f,
Ker f
Coim f)
for this specific object
The map
l:K
A
K
Ke r f
exists,
Coim f)
(K,l)
(respectively:
(respectively:
c, I,J)
the cokernel, the image, the coimage)
and use the notation
~
in
(J , p) )
C,
is any map in
then we have a distinguished representative element (respectively:
A.
(respectively:
(respectively: K
n:B
Cok f,
(respectively: ~
C, k:I
-+
B, p:A
then called the canonical injection (respectively:
1m f,
C,I,J). -+
J)
is
the canoni-
cal projection; the canonical injection; the canonical projection) . Theorem 5. be a map in
Let C
C
be a pOinted category, and let
such that
Ker f,
Cok f,
1m f
and
f:A
~
B
Coim f
all
34
Section 3
exist.
Let
and let
1:
Ker f ->- A, and
71: B ->- Cok f
tions.
k: 1m f ->- B
be the canonical inj ections be the canonical projec-
p:A ->-Coimf
Then there exists a unique map a:Coim f ->- 1m f
such that the diagram (Ker
f
f)~}
f)
'r~ICOk
(Coim f)_a_:> (1m f)
is commutative. Proof: image,
We have since
e:
map Since
p (1)
Since that
f
01 ~O.
(Coim f, p)
(Coim f) ->- B
Therefore,
is a cokernel of
such that
e
0
p
~
f.
1,
Then
there exists a 71 08 0 P = 71 0 f = O.
is an epimorphism this implies that 7108=0.
(1mf, k) (1m f, k)
is an image of is a kernel of
we have that there exists a map 8 = ka.
by definition of the co-
f, 71.
we have by Definition 4 Therefore by equation (1)
a: Coim f
->
1m f
such that
But then kap=8p=f,
proving existence of from
Coim f
into
kBp=f.
u. 1m f
Now suppose that such that
8
is another map
Abelian Categories
35
Then kap=f=kBp. Since
k
is a monomorphism and
implies that
p
is an epimorphism, this
a = B.
Q.E.D.
If the hypotheses of Theorem 5 hold, a:Coim f
~
1m f
Examples.
deduced is called the factorization map of
In the category of pointed sets,
is a map, Cok f
then
Cok f
(T/~,
is
{to})'
tion on the set
t
T,
t,t' ~f(S); and where T~T/~).
map:
then the map
Coimf =5/f
-1
"~'
where ~
t'
=
if
T/f (S)
iff either
t
=
(T,t ) o
(more precisely,
t'
or both under the natural
the set-theoretic image, and
(i .e. ,
(to)
~
is the equivalence rela-
to is the image of to
Imf =f(S),
f: (S,so)
f.
glued to a point") .
Therefore, in this pointed category, the factorization map a: Coim f
~
1m f
is always an epimorphism-but is not,
in gen-
eral, a monomorphism. In the category of groups, i f f : G ~ H i s a homomorphi sm of groups, then generated by f (G»,
and
Ker f = f
f(Gj~
-1
(1),
Cok f = H/(the normal subgroup
1m f = (the normal subgroup generated by
Coim f = G/Ker f '" f (G) ,
the set-theoretic image.
Therefore, in this pointed category, the factorization map a:Coim f
~
1m f
is always a monomorphism, but is not always
an epimorphism. In the category of abelian groups, morphism of abelian groups, then B/f (A),
Im(f) = f (A)
and
if
Ker f = f-
f:A l
~
(0) ,
Coim f = A/Ker f.
this additive category, the factorization map
B
is a homoCok f =
Therefore in a :Coim f
-+
1m f
Section 3
36
is always an isomorphism. Example 8.
C be the category of all topological abelian
Let
groups and continuous homomorphisms. category, and the description of
Then
C is an additive
Ker, Cok, 1m, and Coim is
similar to case of the category of (abstract) abelian groups, above.
However, if
f:A-+B
is a continuous homomorphism of
topological abelian groups, and if factorization map, then
C!:
is the
Coim f .... 1m f
is always both an epimorphism and
C!
a monomorphism, but is not in general an isomorphism (since has the quotient topology from
Coim f
induced topology from Example 9.
from
C,
Ker f = f
Cok f = B/f (A),
B.
1m f = f (A) ,
to~
A
f:A -+ B
abelian
is a map
with the induced topology
(0)
imag~
B
by the
with the quotient topology
the closure of the set-theoretic image
with the induced topology from quotient-group of
-1
Then if
the quotient-group of
closure of the set-theoretic from
has the
1m f
C be the category of all Hausdorff
Let
we have that A.
while
B).
groups and continuous homomorphisms. in
A
B,
and
Coimf =A/f
-1
(0),
with the quotient topology from
this additive category, the factorization map of a map
the
A.
In
f
is
always a monomorphism,but is not in general an epimorphism. The next definition is very important. Definition 5.
An abelian category is an additive category,
such that (ABl)
Finite direct sums of objects exist.
(AB2)
Kernels and cokernels of maps exist.
(AB3)
If map
f:A-+B C!:
is a map in
(Coim f) -+ (1m f)
A,
then the factorization
is an isomorphism.
Abelian Categories Remarks 1.
and
(AB1)
37
is equivalent to saying,
(ABl.l)
There exists a zero object,
(ABl. 2)
If
A
and
B
objec~
are
exists a direct sum 2.
Since
3.
1m f
and
A,
then there
A 6l B.
Imf =Ker(Cokf) ,
axiom (AB2) implies that
in
Coimf = Cok(Ker f) exist.
Coim f
In view of axiom (ABl) and Corollary 1.1, if a
A admits an additive structure such that it is an
category
abelian category, then that additive structure is unique. Therefore, an abelian category can be thought of, equivalently, as being a category A
structure on
A,
such that there exists an additive
such that axioms (ABl) ,
(AB2) and (AB3) all
hold. 4.
Suppose that we have an additive category
that axioms (ABl) and (AB2) both hold. If
f:A -+ B
is a map in
A
such
Suppose also that
then the factorization map
is both a monomorphism and an epimorphism.
a:(Coimf) -+Im(f) Then is
A,
A
an abelian category?
To the best of my knowledge,
this question has not yet been settled.
(See, however, the
last paragraph of section 4 below.) Example.
Of Examples 1-9 above, the only one that is an abelian
category is Example 3, the category of abelian groups. Example 10.
The category of all left modules over a fixed ring
with identity Example 11.
R
is an abelian category.
The category of all sheaves of abelian groups
on a fixed topological space Example 12.
If
A
X
is an abelian category.
is a category, and if
that isa set, then we let
C A ,
C
is a category
the exponent category, denote
S(X)
38
Section 3
the category having for objects all covariant functors from C
into
tors.
and for maps all natural transformations of func-
A,
(This useful notation is original to Joseph D'Atri of
Rutgers University, Newark.)
A is an abelian (respectively:
Then if
C
pointed) category, and if
C A
then
additive;
is any category that is a set,
~s an abelian (respectively:
additive; pointed) cate-
gory. Example 13. category
A be an abelian category.
Let
AO is an abelian category.
Example 14.
Let
A
pointed) category. complexes
Definition 6.
be
a
Then the category
of all cochain
indexed by all the integers is an abelian nE;?" additive; pointed) category.
Let
A
be an abelian category, and let
sequence of maps in the category (1)
subobjects of
B.
Example.
A
Let
is exact at spot
F~G
B
A. iff
Then we say that Ker g = 1m f
be an abelian category and let
gory that is a set.
AB
Co(A)
additive;
f g A -->B-->C
the sequence
in
be an abelian (respectively:
n (en,d )
(respectively:
(1)
Then the dual
S
as
be a cate-
Then a sequence
__ H
is exact at spot
the sequence F(B) -+G(B) -+H(B)
G
iff for every object
B
of
S,
Abelian Categories is exact at spot
G(B)
39
in the abelian category
A.
A is an abelian category, then a sequence:
Similarly, if A*-+B*-+C*
of
7-indexed cochain complexes in
for every integer A
n
-+B
n
is exact at spot
n,
-+C
A is exact at spot B* iff
the sequence
n
Bn.
In Example 11 above, in the category
Six)
of abelian groups on a fixed topological space
of sheaves of abelian groups iff for every F
x
x E X,
-+G
x
-+H
in
SiX)
of sheaves X, a sequence
is exact at spot
G
we have that the sequence of stalks:
x
is exact in the category of abelian groups at spot
G .
x For the rest of this section, we state several theorems,
for arbitrary abelian categories
A,
all of which are easy to
prove, or well-known, in the case that abelian groups.
A is the category of
By the Exact Imbedding Theorem, see sect.4, we
therefore have these results in all abelian categories. Proposition 7. f (1)
A be an abelian category, and let
Let g
A-->E~C
be a sequence of maps in of
B
iff
A.
Coker f = Coim g
Then
Ker f = 1m g
as subobjects
as quotient-objects of
B.
40
Section 3
Note:
By Definition 6 above, an equivalent statement is:
"Then the sequence (1)
A
category
is exact at spot
B
in the abelian
iff the sequence
g f C_>B-->A in the dual category Proof:
AO
is exact in
The proof is easy if
groups.
A
AO
at spot
B.
is the category of abelian
By the Exact Imbedding Theorem (see 'section 4),
it follows that it is true for all abelian categories.
8.
Proposition
Let
A
be an abelian category, and let
an object in
A.
(K,i)
associates the quotient-object
of
A
A
be
Then the function which, to every subobject is a
Coker(i) ,
one-to-one, order-reversing, correspondence from the class of all subobjects of of
A.
The inverse correspondence is also order-reversing, and
is the one
that, to every quotient-object
ciates the subobject Remark:
A onto the class of all quotient-objects
Ker
~
(C.~)
of
A,
asso-
.
In the statement of Proposition 8 above, we must make
the conventions of section 2, just after Definitions 1 and 1
0
,
since otherwise one cannot speak of the "class of all subobjects" or the "class of all quotient-objects" of an object Proof:
Same as Proposition 7.
Proposi tion Let
A
9.
(Fundamental Theorem of Homological Algebra) .
be an abelian category, and let f*
(1)
A.
0 ....
g*
A*~B*---l>C* -+
0
Abelian Categories
41
be a short exact sequence(*) in the abelian category ~-indexed
of all
category
A
cochain complexes
(Example 14 above).
Co(A)
of objects and maps in the
Then there is induced a
long exact sequence of cohomology: n-l n n n d_ _> Hn (A*) H (f*» Hn (B*) H (g*» Hn (C*) ~>Hn+l (A*)
-l>-
•
Moreover, given a commutative diagram with exact rows,
o-:r rl f*
g*
,:t"
O_ _ 'A*~'B*~> ·C*
0 4-
0
in the abelian category eo(A), we have that the diagrams:
commute in the category Proof:
If
A
A,
for all integers
n.
is the category of abelian groups, then this
theorem is well-known, see [C.E.H.A.l.
By the Exact Imbedding
Theorem (see section 4 below), it follows that it holds for all
abelian categories
A.
Finally, we conclude this section with a few elementary definitions about functors of abelian categories. Definition 7. F:A~>
gory
S
Let
A and S be additive categories and let
be a functor.
Then we say that the functor
F
is
(*)ThiS means that the sequence (1) in the abelian cateCo(A) is exact at spots A*,B* and C*.
••
•
Section 3
42
addi ti ve iff whenever A
f, g:
A
I
~
A
are maps in the category
then we have that F(f + g) = F(f) + F(g)
in Remark.
F:A~>
By Proposition 1, we have that, if
B
is an
additive functor of additive categories, then
F
preserves
finite direct sums when defined.
n
is an integer
~o,
and if
sum sum
AI' ... ,A
Al (Jl ... (Jl An
That is, if
are objects of
n
A
exists in the category
F(A ) al ••• (Jl F(A ) n l
such that the direct A,
t hen the direct
exists in the category
(3,
and the
natural map is an isomorphism:
Conversely, by the proof of Corollary 1.1 , if (3
are additive categories, and if the category
that, for every object then a functor
A
in
A,
the direct sum:
is additive iff
F:A~>(3
A
F
A
and
is such A(JlA
exists,
preserves finite
direct sums when defined iff F preserves A(JlA, for all A in
A.
In particular, a functor of abelian categories is additive iff it preserves finite direct sums of objects. Definition 8. F:A~>
(3
Let
A
and
be a functor.
(respectively:
B
be abelian categories, and let
Then the functor
right exact; exact) iff
F F
is left exact is additive, and in
addition whenever
o~
f I
fll
A'---:>A~A"-"O
is a short exact sequence in the abelian category
A,
then the
Abelian Categories
43
sequence: F(f' ) F(f") 0 .... F(A') ----'"p(A) -----...;*'(A") (respectively:
the sequence
F (f')
F(f")
F(A')--~)F(A)--~)F(A") -+
0;
the sequence F(f' ) 0 .... F(A')
---~*,(A)
F(f") ----'»F(A") .... 0)
is exact in the abelian category Remarks 1.
An additive functor
exact (respectively: (respectively: 2.
B. of abelian categories is left
right exact) iff it preserves kernels
cokernels).
(See [C.E.H.A.l ).
It is not difficult to show that a functor of
abelian categories is left exact (respectively: iff it preserves finite inverse (respectively: limits.
right exact) finite direct)
(This can be interpreted as meaning "direct (respec-
tively: inverse) limits over finite pre-ordered sets, as defined in [c.A.l": or the more general "direct (respectively: inverse) limits over fini te
categorie~1
(meaning categories that
have only finitely many objects and such that all of the Hom's are fini tel ) . 3.
A
functor of abelian
categories is exact iff it
is both left exact and right exact. The
next section is a faithful reproduction of an earlier
paper by the author,
[I.A.C.l.
Appreciation is expressed by
the author to the original publisher for allowing such reproduction.
Section 4 Imbedding of Abelian Categories
1.
Introduction.
In this section we prove the following
EXACT IMBEDDING THEOREM.
Every abelian category (whose objects
form a set) admits an additive imbedding into the category of groups which carries exact sequences into exact se-
a~elian
quences. As a consequence of this theorem, every object has "elements"- namely,
the elements of the image
A A'
A
of of
A
under the imbedding--and all the usual propositions and constructions performed by means of "diagram chasing" may be carried out in an arbitrary abelian category precisely as in the cateqory of abelian groups. In fact,
A
if we identify
with its image
imbedding, then a sequence is exact in an exact sequence of abelian groups. image, and coimage of a map image, and coimage of map
f
f
f
of
A
A'
under the
if and only if it is
The kernel, cokernel,
A are the kernel, cokernel,
in the category of abelian groups; the
is an epimorphism, monomorphism, or isomorphism if and
only if it has the corresponding property considered as a map of abelian groups. of
A
The direct product of finitely many objects
is their direct product as abelian groups.
then every subobject of
A
is a subgroup of
A,
tersection (or sum) of finitely many subobjects of
44
If
A E A,
and the inA
is their
Imbedding of Abelian Categories
45
ordinary intersection (or sum); the direct (or inverse) image of a subobject of
A
by a map of
direct (or inverse) image.
are maps in
A
is the usual set-theoretic
Moreover, if
and the set-theoretic composite
A,
then this composite AO -+ A + l ' 2n is the image of a unique map of A, this map of A being inis a well-defined function
dependent of the exact imbedding
A~>{abelian
groups} chosen.
In particular, many of the proofs and constructions in le.A.)
remain valid in an abstract abelian category-e.g., the
Five Lemma, the construction of connecting homomorphisms, etc. If the abelian category
A
is not a set, then each of its
objects is represented under the imbedding by a group that need not be a set. I am very grateful to Professor S. Eilenberg for the encouragement and patience he has shown during the wri ting of this paper. 2.
Exhaustive systems.
In
§§2-4,
A
denotes a fixed
set-theoretically legitimate abelian category, and
E
the cate-
gory of abelian groups. An exhaustive system of monomorphisms in an abelian cate,) 'ED' of monomorphismf gory A is a non-empty direct system (A"a, ~ ~J ~ in A such that: (E) If iED exists
j,;i
Lemma 1. in
A
such that
If
(1'•. , a .. ) ~
~J
and f:Ai-+B is a monomorphism then therE 0ij=f.
is an exhaustive system of monomorphisms
then (1.1)
there exists
If
f,f':A'-+A iE D
are maps in
such that
A
and
flf'
Hom(f,A ) I Hom(f' ,Ai)' i
then
46
Section 4
(1.2)
f:A .... B
If
is a monomorphism, j > i
a map then there exists
Proof.
Let
(1.1).
iED
A.=A(!)A .. J ~
Hom (f , Ai)
and
(1.2).
A -> B (!) Ai
I
,
D
D
in
(C,y)
3.
so that
h A.--------;>.;C
g
k
k
A-----f
is the composite
Ai .... B (!) Ai .... C,
we have
there exists
kf = Ctijg,
Then
hE Hom(A,A.), J
f
(E).
But
f, -g.
/"
By
be the injection.
i
be the cokernel of the map
A------~
site
i
such that
y
B (!) Ai
h
J
be the injection.
h Ai -----'!>-:.c1.:
Then if
k: B .... A.
g:A->A
such that
disagree on
with coordinates
g
and
A j) .
Let
~
and
g:Ai->A(!)A
h:A->A. J
Hom (f I ,Ai)
Hom (f , A j) "I Hom (f Proof.
Let
and j ~ i
Then by (E) there exists then
in
iED
j > i
B .... B (!) Ai .... C,
and
kf = hg,
k
and
such that
k
the compo-
is a monomorphism.
(). .. = h. 1J
Then
as required.
Q.E.D.
The basic construction.
In this section, we shall
prove Theorem 1.
If
A
is an abelian category then there exists an
exhaustive system of monomorphisms in
A.
We first obtain some preliminary results. Lemma 1. phisms in
If
A,
(Ai,Ctij)i,jEI and
is a directed system of monomorf:A. .... B 10
is a monomorphism,
Imbedding of Abelian Categories
47
then there exists a direct system of monomorphisms extending
Let
I' = I U J*
J*
be a set equipot9nt to
j -> j *
be a bijection from
j, k
i E I,
i
~
For A.
E J,
j
~
~ j
let
J,
j* iff
*
~
and diSjoint from
J
onto
iff
k*
I j ~
J* .
Let
as a directed subj E
for
k;
J
and
i ::. j .
be the cokernel of the map
Aj *
with coordinates the maps
J
-f:A.
and
i,
+ A. Ell B
1.0
J
be the directed set containing
set such that, for *
I'
be the directed subset of r consisting of all
J
i ~ i O' Let r, and let
j
in
j > i
a ij = f.
such that Proof.
and a
a . . :A.->A. 1. 0 J
and
1.0 J
Then we have a commutative diagram of monomorphisms:
+B.
1.0
B
f'
fl A. 1.0 a.1.
oA.
0
,j
J
is functorial,
The assigment
so
that for
we have a monomorphism i E I,
and
i
j*
~
in
I',
then define
a .. * 1., J
<x ••
Ai ~Aj ->A j *.
posite
A.
in
Then
familY of monomorphisms in
in
j ~ k
J,
If to be the comis a direct
A extending
(Ai,aij)i,jEI
and Q.E.D.
Lemma 2. in
A,
If
(Ai'<Xij)i,jEI
then there exists a direct system
monomorphisms extending i E rand j ~ i
is a direct system of monomorphisms
in
f:A.
1.
I'
-+ B
with
(Ai,uij)i,jEI
is a monomorphism in a .. = f. 1.J
(Ai,aij)i,jEI'
such that, whenever
A,
there exists
of
48
Section 4
Proof.
Let
and
is a monomorphism of
f
P
be the set of all pairs
by a relation
P
family
;,.
(A, ,a., ,).
. "I
Having defined put
D(k,f) =IU
family
A . k
k EI
Well-order
define a directed
of monomorphisms as follows:
1J 1,
"
for
(k',f') < (k,f),
(k', f ' )
(k',f'Y«k,f)I(k',f')' Then apply Lemma 1 to the
(A. ,Cl. .. ). 1
(k, f) E p,
(A" Cl. .. ), j"I ].
where
A with domain
For each
1J 1,J" (k,f)
1
(k, f)
let
'CD
1J 1,J" (1<, f)
(A. ,Cl. .. ). 1
'CI
1J 1,J" (k,f)
be the
family obtained. Put
I' =
(k,~)EP I(k,f)" Then the family
(Ai,Cl.ij)i,jEI'
has the desired properties. Proposition 1.
If
££QQf.
(Ai,Cl.ij)i,jED
A,
monomorphisms in
Q.E.D. is any direct system of
then there exists an exhaustive system
For each non-negative integer
let
q,
be defined inductively by: DO = D. (A. ,Cl. .. ). 1
Having defined
'ED
1J 1, J
Lemma 2 to
(Ai' Cl. ij ) i, j ED
'
let
q
be the direct system obtained by applying
q+l
(Ai,Cl.ij)i,jED • q
putting
D' =
~oD
q=
q
is an
we see that
,
Q.E.D.
exhaustive system of monomorphisms. Proof of Theorem 1. single element
i.
Let Let
be the identity map of
D Ai A .• 1
system of monomorphisms of
be a directed set consisting of a be any object of
A,
and
Cl.,
.
1,1
Then
A.
Proposition 1 completes the
proof. Remark.
Note that the cardinal number of the indexing set of
Imbedding of Abelian Categories
49
the exhaustive systems we have constructed is that of the set of monomorphisms of
4.
A.
(This is so even if
The limiting process.
system of
F:A*-+ E
by
(A.
~
D.
is not a set.)
be an exhaustive
,CI. . . ) ~J
in the abelian category
mo~omorphisms
by the directed set
Let
A
A,
indexed
Define a functor F(f) = l,tm Hom(F,A ) . i
F(A) = l,tm Hom(A,Ai)'
~
~
Then it is easy to see that
F,
being the direct limit of
additive, left-exact functors mapping into
E,
is itself left-
exact and additive. Lemma 1.
The functor
F
is an exact imbedding(l) from
A*
E.
into Proof.
If
A-IA'
Hom (A' ,A.) = ¢.
A,
in
i E D,
then for each
Hence, the abelian groups
F (A)
Hom(A, A.)n ~
and
F (A' )
~
are disjoint and therefore distinct. If exists maps:
f
l
,f :A' -+A 2
i ED
are maps in
such that
Hom(A,A ) -+F(A), i
A,
then by (1.1) there
Hom(fl,A ) -I Hom(f ,A ). i 2 i Hom(A',A ) -+F(A'), i
limit of monomorphisms in the category
E,
The canonical
being the direct are monomorphisms.
Hence, considering the commutative diagrams F(f .) F(A)
J
I
>F(A')
1
Hom (f. ,A. ) Hom(A,A. ) _ _ _~J'--_~-7> Hom(A' ,A.) ~
~
(l)Recall that an imbedding from a category A into a category B is an isomorph~sm from A onto a subcategory of
B.
50
Section 4
for
j = 1, 2,
F(f ) i- F(f ). l 2
we see that
Hence,
F
is an im-
bedding. If
f:B-+A
is an epimorphism of abelian groups. then let
g EHom(A,A.)
k:B-+A.
g:A-+A.
1
as in (1.
J
represent
1
morphism and
Hom (A, a .. ) g. lJ by k. Then
Let
A*,
is an epimorphism in
2) •
In fact,
g.
kf = a
k EF(B)
ij
g,
F(f):F(B) -+F(A)
if
g
f:A-+B
Then
is a map; choose Then
then
in
j ~ i
~F(A),
is a monoD
and
Hom ( f , A . ) k =
i.e. ,
J
be the element of
F(B)
represented
chasing elements in the commutative diagram:
kEF (B) _ _F_(.c-f _)_ _----.,) F (A~
1
Hom (A, A. ) 3 g
j
HOm(A, Hom(f, A.) k E Hom (B , A . ) _ _ _ _ _J"'--~) Hom (A, A . )
we see that
J
a:
j)
J
F(f) (k) =g,
as required.
Since we have already observed that
F
is left exact,
the theorem follows.
Q.E.D.
Applying Theorem 1 and Lemma 1 to the dual category
A*,
A admits an (additive) exact imbedding into
we see that
E,
which proves the Exact Imbedding Theorem. 5.
Generalizations.
It should be clear that the proof
of the Exact Imbedding Theorem can be extended to arbitrary categories. If equalizer
In this section, we state such a generalization.
f,g:A-+B E(f,g)
subobject of category,
A
are maps in the category of
f
on which
and
g
f
and
E(Lg) =Ker(f-g),
A,
thenthe
(when defined) is the biggest g
agree.
Ker(£) =E(f,O).
In an additive so that
Imbedding of Abelian Categories
51
"equalizer" is a generalization of "kernel" to arbitrary categories. Theorem.
Let
A be a set-theortically legitimate category
closed under direct products of two objects and equalizers of two maps.
Then the following three conditions are equiva-
lent:
A admits an imbedding into the category of nonempty
1.
sets preserving monomorphisms, epimorphisms, equalizers, and finite direct products.
A
2.
admits an imbedding into the category of nonempty
sets preserving epimorphisms, equalizers, and finite direct products. 3.
with
g
Every diagram:
an epimorphism can be imbedded in a commutative
diagram:
A--+B
with
h
AxB-+A,
an epimorphism.
Moreover, the canonical map,
is an epimorphism.
In addition, if the category then we
A is pointed or additive,
may assume that the imbeddings in 1 and 2 take values
in the category of pointed sets or abelian groups.
52
Section 4 6.
Element techniques in an abstract abelian category.
In this section, we prove the assertions made in
E.
exact imbeddings into
§l
about
We consider only abelian categories.
It is easy to see that, in an abelian category, if with
k
a monomorphism and
image and
i
i
an epimorphism, then
is a coimage of
f.
f = ki
k
is an
This is seen by considering
the commutative diagram: ---~)L
I~----
where
K,L
and
and image of Theorem 2.
f, Let
are, respectively, the kernel, cokernel,
and F
a
Al~A~A3
be an exact imbedding from the abelian
Necessity is clear; let us prove sufficiency.
Hence, if
such that
of
is exact in
.!...LtlF (A ) 3
since
Then a sequence
B.
that fg=O.
B.
A if and only if the image
is exact in
sequence-is exact in Proof.
is uniquely determined.
A into the abelian category
category (1)
I'
k=kernel(f)
g=ki.
But
whence
a monomorphism in and (1) is exact in
i
A,
Then
then there exists
F(k) = kernel (F(f))=image(F(g))
F (g) = F (k) F (i) ,
F(g),
in
B.
Suppose
it follows that
F(i)
is an epimorphism in
A.
Since
9 = ki
A;
Henceforth, fixing an exact imbedding into
S;
is the coimage clearly
it follows that
A.
in
i
k
is
k = image (g) , Q.E.D.
E for each
abelian category, we use freely the set-theoretic properties
53
Imbedding of Abelian Categories of objects and maps in abelian categories. If
A,BEA,
subobject
R
then an (additive) relation
of
AxB.
If
R:A-+B
then their composite
SR
A x B x B x C -+ A x C
(R x S)
diagonal of
of
B x B.
and
R:A-+B
S:B-+C
is a
are relations,
is the image under the projection
n
(P.
x /':, x C),
where
/':,
is the
Since this coincides with the set-theoretic
definition, composition of relations is associative. Similarly, one defines the inverse relation proves that (R-l)-l If A -+ A
x B
f:A-+B
R
-1
and
,
=R.
isamapin
A,
wi th coordinates
then the image of the map is the graph
f
it is the ordinary set-theoretic graph. one-to-one and preserves composites. R · f The relation R
R f
of
f;
Hence,
We identify the map
f
with its graph
the composite F:A
->-
B
is a
R -+ A x B ->- A
(graph of some) map if and only if is an isomorphism.
Hence, if
R
is an exact imbedding of abelian categories, then
is a map if and only if
F(R)
is a map.
If in the abelian category
A,
is the
are maps and the relation graph of a map, then this map: inverse-composite and is denoted
AO
->-
A
+ 2n l
is called their
-1
-1
fng n ···gl fo:AO-+A2n+l'
Using the Exact Imbedding Theorem and Theorem 2, we obtain: Theorem 3.
(Axiomatic Definition of Inverse Composite).
complete characterization of the inverse-composite -If gl 0
of maps
A
Section 4
54
in an abelian category is given by: (ICl)
In the category
composite
E of abelian groups, the inverse-
is defined if and only if the corres-
ponding set-theoretic composite is a single-valued function defined on all of (IC2)
If
AO;
in which case the two coincide.
F:A~>
B is an exact imbedding of abelian f ng
categories, then the inverse-composite fined in
A
if and only if
is defined in F(fn)F(gn)
-1
B;
F(fn}F(gn}
in which case,
... F(gl)
-1
-1
-1
n
-1
... gl fa
... F(gl)
-1
F(fng n ... f
-1
l
-1
is de-
F(f )
o
fa)
F(f o)'
Combining Theorems 2 and 3, we obtain all the properties of exact imbeddings asserted in the Introduction. Added in proof (October 25, 1960).
The theorem of
§5
can be used to characterize abelian categories: Corollary.
If
A
is an additive category such that kernels,
cokernels and finite direct products exist, then
A
is abelian
iff the following three conditions hold: (1)
with
g
diagram:
Every diagram:
an epimorphism can be imbedded in a commutative
Imbedding of Abelian Categories
with
h
an epimorphism.
(2)
Every diagram:
55
A.{-(----- B
with
g
a monomorphism can be imbedded in a commutative
diagram:
hf+----'
19
A~(-----B
with
h
a monomorphism.
(3)
A map that is both an epimorphism and a monomorphism
is an isomorphism. Proof.
In view of (I) and the theorem of
addi tive imbedding
A .... A',
g .... g'
§5,
is the canonical factorization of a map f =;
Coim ( f ' )
k 'z' = 1m (f' );
in
E;
since
whence
k'z',z'
phisms in, respectively, dual category by (3)
z
A*,
f' =k'z'h',
E,E
we see that
is an isomorphism.
Hence, if of
z
A.
A,
f=kzh
then
we must have
and therefore and
admits an
E preserving kernels
into
and epimorphisms, and hence also coimages.
h'
A
z
are monomor-
Applying (2) to the
is an epimorphism.
Hence Q.E.D.
Section 5 Subquotients
A be an abelian category and let
Let objects. from
Then recall
A
into
A
jects in
B
and
B
be
([I.A.C.]). that an additive relation
is a subobject of
and
A
R:A.,. Band
Ax B.
S:B.,. C
If
A.B.C
R
are ob-
are additive relations.
then see [I.A.C.] for the definition of the composite relation S
0
R:A -+ C;
R-I:B-+A
and we also have the inverse relation of ([LA.C.]).
have the graph of
f.
----
into
Remark.
Let
ject in
A.
iff
of
A.
Let
B B
B
an additive relation from
A
A
be an ob-
be another object in the category Imbeddin~i
is isomorphic to a
A.
Theorem. it is easy to prove subobject of
subobject of a quotient-object
B B
-1
R = r lor 'IT
B
A be an abelian category and let
Let
A.
Then consider the class
is an object in into
a monomorphism
where
then we
This motivates the following definition.
object in
from
A.
is isomorphic to a quotient-object of a
Definition.
where
rf:A-+B.
is a map in
A be an abelian category and let
Then using the Exact
A
f:A-+B
([LA.C]).
B
that:
If
R.
A.
A and
R
SA
is an object in
SA
'IT:C -+B
C
56
R
in
A.
such that
is the class of all pairs
A and
(B.R)
is an additive relation
and an epimorphism
(equivalently:
be an
of all pairs
such that there exists an object
l:C -+A
A
(B. R)
is an additive relation
57
Subquotients
from
A,
B
into
A,
such that there exists an object
an epimorphism
that
R = r-
l
p:A ->- C'
or.). J
p
(B' ,R'),
iff
that
A.
ject in class
Then (1)
R' oR=R" (2)
(B",R")
~
(B' ,R')
the additive relation
such
A
be an ob-
in the pre-ordered such that
R:B"->B'
is uniquely determined by this condition, and
By the Exact Imbedding Theorem,
abelian groups.
A
If
(B' ,R') E SA '
and a monomorphism
TT' :C' ->- B'
such that
A
(B",R") E SA'
Then replacing and of
there exists
and an
l":CII-+A
and that
C"
C'
and
C"
Similarly, since
•
A
in
and a monomorphism such that
and
C'
C"
and that
natural maps.
B'
by
Similarly,
R'
1 "
o
TT': B' ->- C'
and
Then from the relation
{(a' +K',a'):a'E C'}.
by
B' =C'/K',
TT":B"->-C" R'=r
B"
1 '
are the or- l TI
I
'
we de-
-1
r 7f
B'""C'/KerTT', and
C'/Ker TT'
duce
(1)
r
are subgroups of
Then
if necessary, we can assume that ,
R" =
by the set-theoretic images of
are the inclusions.
Replacing
C'
and an epimorphism
'TTII:C" -+BII
epimor~hism
1',1"
B"""C"/Ker TT".
Ell = CIl/K Il
l orr; I
I
we can assume that
1",
C"/Ker TT"
1
is the category of
there exists an object
1': C' ->- A
R'=r
it suffices
[LA.C.l,
to prove the Lemma in the case in which
A,
~
(B" ,R) E SB' .
Proof:
in
by
R: B" ->- B'
be an abelian category and let
Suppose that
SA"
SA'
Then,
A
Let
such
(B",R")
that
there exists an addi ti ve relation
R' °R=R".
Lemma 1.
(B",R")E SA'
in
j : B ->- C'
We have a pre-order on the class
defining, whenever (B' ,R')
and a monomorphism
C'
II •
Section 5
58
(2) If
{(a" +K",a") :a" EC"}.
R"
(B",R").s.(B',R')
in
an additive relation
then by definition there exists
R:B"-+B',
such that
R' °R=R".
(3)
If
SA'
ailE C",
therefore
then
(a" +K",a") ER' oR.
there must exist (0.,13) E R,
(a"+K",a")E R".
suchthat
particular
a
II
Therefore, by equation (1)
(so that
a'E C'
a
II
E C"
a
I
(a' + K I , a') E R'»
and
(a,a') = (a" +K",a").
S=a'+K',
= a' E C'.
By equation (3),
being arbitrary,
In
it follows
that (4)
C" CC ' •
Also, we have a
= (a
II
+ K").
(5) If
(a,S)ER,
= all
Therefore
{(a"+K",a"+K') :a"E C"}c R.
h' E K'
then by equation (1),
in equation (5), we have that equation (3), we have that
(aU+KII,a ll ) ;
II
E K ".
a" E C" a" =h'
h' E K'
Taking
a" = 0
Therefore by
(K",h')E R' oR=R".
i.e., such that
h' = a
(K' ,h') E R'.
(K",K') E R.
tion (2) there therefore exists
Therefore
S=a'+K'=a"+K',
J
But by equa-
such that and such that
(K", h') =
ailE K".
being arbitrary, we have like-
wise that (6)
K'C K".
Next, suppose that
(\!,S)E R,
where
a'E C'.
a" EC"
and
say
a=a"+K",
S=a' +K',
Then by equation (1) we have that
59
Subquotients (a' + K' ,a') E R'.
Therefore from equation (3) we deduce
(a"+K",a')ER'oR'=R". a'EC"
and that
But then by equation (2) we have that
where
(a"+K",a' +K') '= (a' +K",a' +K') C II
a'
is an element of
is an arbitrary element of
(a,5)
Since
•
(a, 5) '=
Therefore
a"+K"'=a'+K".
comparing
R,
with equation (5), we see that R'= {(a" +K",a" +K') :a"E cOIl.
(7)
Therefore, if there exists then indeed
R
R
such that equation (3) holds,
is uniquely determined.
case, the pair
(B", R)
And, when this is the
is indeed an element of
Q.E.D.
SB"
Following the methods of the last Lemma, one can also deduce the following related results. (B' ,R')
If
Corollary 1.1.
(B", R") E SA
and
A,
object in the abelian category
I
where
A
is an
then the following two
conditions are equivalent. (B" ,R") .:. (B' ,R')
Both
2)
There exists an isomorphism
the abelian category R'
0
and
1)
fe'= Ril,
A,
(B', R') .::. (B" ,R") e
from
B"
in
onto
SA·
B'
in
necessarily unique, such that
as subobjects of
B"xA.
This motivates another definition. Definition. object in
A be an abelian category and let
Let
A.
of pairs in
Then a subguotient of SA
where two pairs
I
are eguivalent iff both in
(B' ,R')
~
A
A be an
is an equivalence class
(B' ,R'),
(B", R")
in
(B" ,R")
and
(B", R")
.s.
(B' ,R')
SA·
ExamQle 1. object in
Let
A.
A Let
be an abelian category and let cII,e I
be subobjects of
A
A
be an
such that
C" cC' .
60
Section 5
Let
B
be the quotient- object
inclusion and (B,R)
IT:C'
-+
C'/C"
is an element of where
C' /C".
If
l:C'
-+
A
is the
is the natural map, then the pair
SA '
and therefore defines a sub-1 or . IT
quotient of
A,
quotient of
A
the
subquotient
Corollary 1.2.
Let
A be an abelian category and let
A.
an object in
If
R=r
1
{(B,R)}
there exist unique subobjects COl eC',
and such that
We will call this sub-
C' /C".
is a C'
subquotient of and
C"
of
A
A,
A,
be
then
such that
{(B,R)} = C'/C".
Of course, this Corollary is proved along the same lines as the Lemma. Example 2.
A.
category of
A.
Let
C
be any subobject of
A
Then by Example 1, we have the subquotient
Notice, by the last Corollary, that, if
subobjects
of
(Explicitly, if subquotient of
A,
then, as subquotients of
C A
is a subobject of
A,
(O,R)
A,
Thus, the "object part" of the subquotient are the same even if
and C/C
CiC
C/C are
O
C/c"I CO/CO. C/C
is the
where
0
is
R = 0 x C(cO x A). and
CO/CO
C t- CO' - namely, both are the zero object-
but the "relation parts" of
C/C
and of
CO/CO
are different
C"lCO).
Corollary 1.3.
A.
A,
then
represented by the pair
the zero object in the abelian category
if
in the abelian
Let
Q
and
Let Q O
A
be an object in the abelian category
be subquotients of
Corollary there exist unique subobjects such that Q = CO/ce;. O
C'::JC",
Co::JCo
and such that
A.
Then by the last
C',C", CO,C
O
of
A
Q=C'/C",
Then the following two conditions are equivalent:
Subquotients 2)
COCC'
and
61
Co::::lC".
The proof of this Corollary closely follows that of the Lemma. Example 3. object in
A be an abelian category and let
Let A.
Then. by definition. every subobject of
an equivalence class of pairs \ :C
A
-+
(C.\)
where
C
A
~
\8.
Then by Lemma 1. it follows that:
is a subquotient of
A
A
(literally).
in
A
8
sub object of
Every subobject of
In like fashior. every
is a subquotient of
regarded as a subquotient of
A.
two subobj ects of
A
A.
object) and
C.
Similarly. if
Q
then regarded as a subquotient of of subobjects of
A
If
C and
Co
K
as subquotients of
A
A,
then
BO .:::. B
A
in
K
and
A
(the
quotient-objects) of
COCC
(resp.: of
A
Co':::' C)
A as
iff
A. if
B
quotient-object)
as subquotient of
object (resp,:
A,
the corresponding pair
as quotient-objects)
in the abelian category
subobject (resp.:
(the zero
is the kernel of the natural map:
Also, it follows that, object
A,
are subobjects (resp.:
(resp.:
0
therefore from the last Corollary that:
in the abelian category subobjects
is
then the
is a quotient-object of
by Corollary 1.2 are
whole subobject), where It follows
A.
C
that correspond to this subquotient
under the correspondence of Corollary 1.2 are
Q.
is
such that
Under the correspondence of the Corollary 1.2. if
A -+
A
is a monomorphism. two such pairs
quotient- object of
a
be an
is an object and
being equivalent iff there exists an isomorphism \0
A
A,
then
quotient object) of
is any subquotient of an A, BO B A.
and if there exists a of
A
such that
must also be a sub-
62
Section 5 From the Corollary 1.3, it also follows that:
Corollary 1.4. let
I
object
Let
A
be an object in the abelian category
be a set, and let A.
Write
B , i
B.=C.'/C'.', ~
~
~
i E I, all
A,
be subquotients of the where
i E I,
the uniquely determined subobjects of
A,
all
C'.' c: ~
i E I.
C~
are
~
Then
the following two conditions are equivalent: 1)
There
ex~sts
is an infimum (resp. :
2)
B
of the object B. ,
supremum) of the
(b)
C'
There exists a subobject
C"
(resp. :
C". ,
infimum) of the
that
that is an infimum
Cit
supremum) of the
A
iE I .
~
There exists a subobject
(a)
(resp. : and
a subquotient
i E I. that is a supremum i E I.
~
When these two equivalent conditions hold, then we have that B=C'/C". In terms of
sub quotients, every addi ti ve relation admits
a canonical factorization. Theorem 2.
Let
to the object subquotients
R B
A'
be an additive relation from the object
in the abelian category of
choose representatives
A
and
B'
of
(A",R") E A'
there exists an isomorphism
B,
Then there exist
such that if we
and
8 :A" ~ B",
A.
A
(B",S") E B',
then
such that the diagram
of objects and additive relations:
is commutative.
The subquotients
A'
of
A
and \B'
of
B
Subquotients
63
are uniquely determined; and so is the isomorphism (A" ,R") EA'
selects representatives
and
8
once one
(B", S") E B'.
The proof is trivial and left as an exercise.
An equiva-
lent formulation is: corollary 2.1. A
Let
to the object
be an additive relation from the object
R
B
in the abelian category
exist uniquely determined subobjects and
A"e: A'
Ab
EA',
B', B"
of
and
B6 E B'
B
wi th
BO E B"
A' ,A"
B "e: B'
R
where
of
Then there A
with
such that, if
AOEA",
are any representative elements,
then there exists a unique isomorphism that
A.
8·A'/A"""B'/B" . 0 0 0 0
such
is the composite relation:
1
:Ao
-+
p : B6 -+ B6/Bo
A,
j : BO
-+
B
are the inclusions and
R;
B"
R.
Then
R
R;
and
and images of
R R
is the domain of the
B'
R
R;
A"
is
is the image of the
is the graph of a
determined) map iff the domain of ambiguity of
A'
is the ambiguity of the relation
the kernel of the relation relation
:Ab -+ Ab/Ao'
are the proj ections.
We introduce the terminology: relation
1\
(necessarily uniquely
is all of
A,
and the
(in which case, of course, the kernel
is zero
then coincide with those of the uniquely
determined map of which
R
is the graph).
also define that the additive relation
R
Perhaps, one might is well-defined
(resp.:
everywhere defined) iff the ambiguity of
(resp.:
the domain of
R
is all of
R
is zero
A).
Yet another way of formulating the above theorem and corol-
64
Section 5
lary, is: Corollary 2.2. A
into the object
A'
of
if
(AO,l) E A'
map
Let
A
f :AO
R
be an additive relation from the object
B.
Then there exists a unique subobject
and a unique quotient-object
-+
Q
O
(QO,TI) E Q',
and
such that
Q'
of
B
such that
then there exists a unique
is the composite
R
(r )-1 TI ) B.
A
Thus, essentially, to give an additive relation from to
B
A is equivalent to giving
in the abelian category A;
(2)
(1)
A subobject of
(3)
A map in the category
the quotient-object of
A
A quotient-object of
B;
A from the subobject of
and A
into
B.
Finally, as in section 2, let us make a very minor convention.
Namely, if
object in
A,
A
is an abelian category and
A
is an
then by the (strongest form) of the Axiom of
Choice, see [K.G.)
(which is consistent with the other axioms
of Godel's set theory, if those other axioms are themselves consistent, see [K.G.)} there exists a subclass ordered class
SA
equivalence class.
S'
A
of the pre-
that contains exactly one element from each Make such a brutal choice.
class of all subguotients of class
SA
A
Then by the
we will mean this indicated
(containing exactly one representative from each
subquotient). (As in section 2, the reason why we do this is that, in Godel's set theory, one cannot
speak
of a class
some of the elements of which are proper classes. in Godel's set theory, one cannot use the phrase of all subquotients of
A"
in the literal sense.)
Therefore, "the class
65
Subquotients Remark:
Using the one-to-one correspondence between subobjects
and quotient-objects of a given object in an abelian category, one way to affect such a choice of representatives for each Suppose that,
subquotient, is as follows. in
A,
and also a complete set of representa-
A,
tives for the quotient-objects of AO
A,
in
Given any
follows.
AO
Then, given any specific
can be constructed as
sub:::!uotient
1.2 there exist unique such that
A.
a complete set of representatives for all
of the subquotients of
C"c C'
Q=C'/C".
of
Q
surobj ects
sentative for the subobject
AO'
C'
and
Then, let of
C'
Then the pair
-1
(QO,f ,Of,,) lO
subquotient
Q
of
lTO
AO.
by Corollary COO
of
(CO' l6)
AO '
and let
be the representative for the quotient-object
the
A
we choose both a complete set of representatives for
the subobjects of
object
for every object
with
A
be the repre(QO'lTO)
C'/C"
of
CO.
is a representative element for Then in this way, we obtain a
complete class of representatives for the subquotients of the object
AO
'
for every object
AO
in
C.
Section 6 Left Coherent Rings
This section is of a somewhat more specialized interest than the rest of this chapter.
The main application, is that
condition (2) of Theorem 5 below
~s
suggested by several
theorems, particularly in Part III, of this book; and it is therefore of some interest to study this condition. All our rings have identity elements, but are not necessarily commutative. Definition 1. Then
M is
Let
All modules are unitary. A
be a ring and let
finitely generated iff
lently, iff modules,
an integer
:3
n 2. 0
an integer
n'::'O
AX I + ... + AX n = M.
xl"" ,x n E M such that
elements
3
M be a left A-module. and
Equi va-
and an. epimorphism of left A-
An ·'M.
M is finitely presented iff there exist non-negative integers
nand
such that Lemma 1.
m
and a homomorphism
q, :A
n
-+
Am
of left A-modules
MR> Cok(q,). Let
A
be a ring and let
M be a left A-module.
Then the following two conditions are equivalent. (1)
M
is finitely generated as left A-module.
(2)
For every set I A 0
M-+ MI
I,
the natural homomorphism:
is surjective.
A
Note.
The proof shows, more generally, that if 66
I
is any set,
Left Coherent Rings then the natural homomorphism:
AI
('9
M~ M
67
is an epimorphism
A
iff every left submodule of
M
that can be generated
by~
card (I) elements, is contained in a finitely generated left submodule of
M.
(1)=(2).
Proof: N'VOO I ® N
Let
¢:An-+M
be an epimorphism.
Since
is an addi ti ve functor, we have that
A (1)
AI@An"'(AI®A)n"'(AI)n"'(An)I, A A
so that the natural mapping:
AI ® An -+ (An) I
is an isomorphism.
A
But then from the commutative diagram with exact rows and columns 0
i
~I
(An) I
') MI - - - - - ' ) 0
T
"l
I ) A ® M---~) 0 A
AI ® An A
T 0 we deduce tha t the natural mapping : AI ~ M -+ MI is an epimorphism. A
(2)=(1). left submodules of by inclusion,
Let M.
D
be the set of all finitely generated
Then
D
is a directed set, pre-ordered
and
Since tensor product commutes with direct limits, this implies that
68
Section 6 AI ®M",llm AI ®N, A NED A
(2)
for all sets
I.
Now let I be a set such that the natural mapping I I is surjective. Then, i f IJM:A ® M -+- M (xi)iEI is any family A of elements of M indexed by the set I, then the element is the image under
of some element of
Then by equation (2), there exists some SEAI®N
such that
IJN(B) = (xi)iEI'
NED
and an element
But then from the commuta-
A
tive diagram: IJ M
AI ® M A
T
IJ N
S E: AI ® N A
I >M :3 (Xi)iEI
J
)N
I
I (xi)iEI E N ,
it follows that
i.e. ,
x. E N, ~
Thus, we have shown that every subset of
for all
M of
i E I.
cardinality~
card (I) is contained in a finitely generated submodule. proves the Note.
And the Lemma follows by taking
cardinality~card
M.
Lemma 2.
be a ring and let
Let
A
left A-module.
Let
n
I
This
to be of
M be a finitely generated n ¢:A -+ M
be a non-negative integer, let
be an epimorphism of left A-modules and let
K = Ker ¢.
Then the
following two conditions are equivalent.
(1)
K
(2)
For every set
is finitely generated as left A-module. I,
the natural mapping:
AI®M-+MI A
is an isomorphism. Note: I,
The proof shows, more precisely, that for any fixed set
the natural mapping:
AI®M-+MI
is an isomorphism, iff:
A
Every left submodule of
K
that can be generated by
~
card (I)
69
Left Coherent Rings
elements, is contained in a finitely generated left submodule of
K.
Proof:
Consider the commutative diagram, with exact rows and
columns 0
0
) (Al) I
) KI
0
iI
~r
1
)A I ® An A
AI ® K A
r
M
,>0
II A ®M A
)0
0
Then by the Five Lemma, the mapping iff the mapping: AI ® K -+ A
the map K
AI ® K -+ KI A
AI@M+MI is a monomorphism. But by Lemma 1, A KI is an epimorphism, for all sets r, iff
is finitely generated as left A-module.
mapping:
is an epimorphism
AI®M-+MI
And, since the
is an epimorphism, we have that thatmapping
A
is an isomorphism iff it is a monomorphism.
Q.E.D.
Lemma 2 has some immediate consequences. Corollary 2.1.
Let
A
generated left A-module.
be a ring and let
M
be a finitely
Then, if there is any integer
n.:: 0
and any epimorphism n ¢ :A -+ M of left A-modules such that
Ker ¢
is finitely generated as left A-module, then
the same is true for every other such pair M
(There is such
a pair
n,¢
ProoK:
Condition (2) of Lemma 2 is independent of the choice
of an integer
iff
n,¢.
n.::O
is of finite presentation.)
andofan epimorphism
¢:An+M.
Therefore,
Section 6
70
if condition (1) should hold for one such pair M
n,¢
if
(i.e.,
is of finite presentation), then condition (1) must hold
for every such pair
n,¢.
Corollary 2.2.
A
ule.
Let
Q.E.D.
be a ring and let
M be a left A-mod-
Then the following two conditions are equivalent.
(1)
M
(2)
For every set
is of finite presentation as left A-module. I,
the natural mapping:
AI 0 M -+ MI A
is an isomorphism. Proof:
By Definition 1 and Lemma 1, both conditions (1)
(2) imply that
M is finitely generated.
to prove the Corollary when there exists an integer
M
n ~0
iff
Ker ¢
Therefore it suffices
is finitely generated. and an epimorphism
By Corollary 2.1, we have that
M
is finitely generated.
and
Then
n ¢ :A
-+
M.
is of finite presentation But by Lemma 2 above we
have that this latter is so iff the natural mapping:
AI ® M
-+
MI
A
is an isomorphism. Remark:
Q.E.D.
A careful checking of the proof of Lemma 2, also
shows that:
"If
A
is a ring,
M
is a left A-module and
I
is a fixed set such that there exists a short exact sequence: O-+K-+P-+M-+O of left A-modules with module of
K,
P
projective, and such that every sub-
that can be generated by .s.- card (I) elements, is
contained in a submodule of the natural mapping:
K
that is finitely generated; then
Left Coherent Rings
71
is a monomorphism." Lemma 3.
Let M'
A
be a ring and let
f'
--~)M------7
M"
--~)O
be an exact sequence of left A-modules. (1)
If
M'
and
M"
f'
is a monomorphism, then
Then
are of finite presentation, and if M
is of finite presenta-
tion. (2)
Proof:
If
M'
and
is
M".
M
M'
Suppose that
are of finite presentation,
then so
is of finite presentation.
Let
I
be a set, and consider the commutative diagram with exact rows
(M') I
~~T AI ® M' A Since AI ® M'
M' ->
(f ') I
)M
B I
)A
I
~(M") I ----~> 0
T
y
T
) AI ® M" ----~)o A
®M
A
.
is of finite presentation, by Corollary 2.2 the map
(M') l i s an isomorphism.
Therefore, by the Five Lemma,
A
if
f'
(and therefore also
is an isomorphism, then
S
(f,)I)
if
B
is an isomorphism then
is an isomorphism, proving (2).
Remark:
y
is an isomorphism, proving (1).
And, again by the Five Lemma, y
is a monomorphism and
Q.E.D.
Lemma 3, part (1), can of course be proved alterna-
tively, using results on projective resolutions in [C.E.H.A.j and making use of projective resolutions generated in dimensions zero and one.
p*
that are finitely
And part (2)
easily proved directly from Definition 1.
can be
72
Section 6 The next Lemma is very well known and is included only for
completeness of exposition. Lemma 4.
Let
A
be a ring and let
M be a right A-module.
Then the following two conditions are equivalent. (1)
M is right flat.
(2)
For every finitely generated left ideal we have that the natural mapping:
I
in
A,
M® I -.. M is injecA
tive. (1)~(2).
( 3)
0
-+
Tensoring the short exact sequence
I -.. A -+ A/I
on the right with (2)~(1).
-+
0
M gives
(2).
Every left ideal can be written as a direct
limit, over a directed set, of finitely generated left subideals. ideal
Therefore, condition (2) implies that, for every left I,
the mapping:
long exact sequence of
M® I -.. M is inj ecti ve. A A
Tori (M, ),
sequence (3), it follows that ideals
I
in
left module
A.
i
~
0,
Applying the
to the short exact
A
TorI (M,A/I) = 0,
for all left
In other words, for every simply generated
N , l
(4)
If
N
is a left module generated by
n
elements,
n
~
1,
then there is a short exact sequence
where
Nn _ l
is generated by
by one element.
n-l
elements and
Nl
is generated
Throwing through the half-exact functor
Left Coherent Rings A
Torl(M, ),
73
and using induction, it follows from equation (4)
that A
Tor I (M, N) = 0, for all finitely generated left A-modules
N.
But then, if 0-;.
f'
N'--t
fn
N~N"
-;.
0
is any short exact sequence of left A-modules such that
N"
is
finitely generated, then we have that (5)
M@f'
is a monomorphism.
A
Now, if f:N' -;. H is any monomorphism of left A-modules, then
H
is the direct
limit, over a directed set, of all the left-submodules H
such that
every such
N/N' is finitely generated. N,
M~(inclusionN'
A
IN
the direct limit over
N,
)
of
By equation (5), for
is injective.
it follows that
N
Passing to
M@f
isinjec-
A
Q.E.D.
tive. Theorem 5.
Let
A
be a ring.
Then the following three condi-
tions are equivalent. (1)
Every left ideal in
A
that is finitely generated
as left A-module, is finitely presented as left A-module. (2) flat.
For every set
I,
the right A-module
AI
is right
74
Section 6 (3 )
For every short exact sequence O~M'-+M-+M"-+O
of left A-modules, M'
if
M and
M"
are finitely presented, then
is finitely presented.
Proof:
(3)
=
Let
(l).
J
be a finitely generated left ideal.
Then we have the short exact sequence of left A-modules
o -+ J A (3)
and J
A/J
-+
A -+
AI J
-+
O.
are finitely presented; therefore, by condition
is finitely presented. Let
(l)~(2).
J
be a finitely generated left ideal.
Then we have the short exact sequence
o -+ J A
and
A/J
-+
A -+
AI J
are finitely presented.
finitely presented. set
I,
-+ 0 •
By condition (1)
J
is
Therefore, by Corollary 2.2, for every
in the commutative diagram
o~
Jf-'Ai TJ)
'_;,0
AI ® J _AI ® A --ioAI ® (A/J)~O A A A the vertical mappings are all isomorphisms. mapping:
AI
®
J +A
A
I
®
A ""AI
is a monomorphism.
This being
A
true for every finitely generated left ideal we have that the right A-module (2)~(3).
Therefore, the
Let
diagram with exact rows,
I
AI
J,
by Lemma 4
is right flat.
be a set, Then in the commutative
Left Coherent Rings
since
M and
M"
7S
are finitely presented, we have by Corollary
2.2 that the rightmost and middle vertical maps are isomorphisms. Therefore, so is the leftmost vertical map. Corollary 2.2,
M'
Corollary 5.1.
Let
And therefore, by
is finitely presented. A
be a ring.
Q.E.D.
Then the following condition
is also equivalent to the three equivalent conditions of Theorem 5.
(3.1)
Given a homomorphism
M .... N
of finitely presented
left A-modules, we have that the kernel is finitely presented. Proof.
Condition (3.1) obviously implies condition (3) of the
Theorem. holds.
Conversely, suppose that condition (3) of the Theorem Let
f:M
-+
N
part ( 2), we have that
denote the homomorphism. Cok f
Then by Lerruna 3,
is of finite presentation.
There-
fore, by condition (3) applied to the short exact sequence
o -+ 1m f .... N .... Cok f .... 0, we have that
1m f
is of finite presentation.
And therefore,
by condition (3) applied to the short exact sequence
o .... Ker
f
-+
N -l> 1m f
it follows that
Ker f
Remarks 1.
A
Let
-+
0,
is of finite presentation.
be a ring.
Then another condition
lent to the conditions of Theorem 5 is
Q.E.D. equiva-
76
Section 6 (3.2)
f,
The full subcategory
having for objects all
the finitely presented left A-modules, of the category
A of
all left A-modules, is an abelian category, such that the inclus ion functor: Proof:
Frvv>
A
is exact.
Clearly (3.2) implies (3.1).
part (2), respectively:
A,
cokernel in
A,
kernel in
Since also
f.
3,
by condition (3.1), we have that the
respectively:
is an object in
Conversely, by Lemma
of any map in
is closed under finite di-
f
rect sums, condition (3.2) follows.
Q.E.D.
Yet another equivalent formulation of condition
2.
(3) is (3.3)
A finitely generated submodule of a finitely pre-
sented left A-module is finitely presented. (3.3)~(3).
Proof:
In fact, given a short exact sequence as
in condition (3), choose an integer An ... M of left A-modules. an epimorphism.
Therefore (3.3),
M'
Then the composite:
M",
The image of M'
we have that
Ker(cjJ)
in
is finitely generated.
Let
is
M
Ker(cjJ)
is finitely
is isomorphic to
M'.
Therefore, by condition
M be a finitely presented left A-
module and let
M'
Then
is finitely presented.
='
cjJ :An ... M"" M"
is finitely presented.
(3)~(3.3).
M"
and an epimorphism:
By Corollary 2.1 applied to the finitely
presented left A-module generated.
n.::. 0
M/M'
be a finitely generated left A-submodule. Therefore, by (3),
is finitely presented. Lemma 6.
Let
A
left A-module, let A-modules.
be a ring, let I
M be a finitely presented
be a set and let N , i
i
EI,
be right
Then the natural induced homomorphism of abelian
M'
77
Left Coherent Rings groups ( II N.) ® M ~ II (N. ® M) , iEI ). A iEI). A is an isomorphism. Proof:
If
M= A
M'V'\,> ( II N.) €I M, iEI ). A
the assertion is clear. M'V\,>
II (N. €I M) iEI ). A
Since the functors
are additive, they preserve
finite direct sums.
Therefore, if
tion is again true.
If now
M
n M=A ,
is an arbitrary finitely pre-
sented left A-module, then there exist integers an epimorphism functors
¢ :A
n
~ Am
such that
M'V\,> ( II N.) €I M, iEI ). A
M'VV>
M "" Cok ¢.
II (N. €1M) iE I ). A
1.
n,
m.:::.
°
and
But, since the
are right-exact, it
follows that we also have an isomorphism for Remarks:
the asser-
n'::O,
Q.E.D.
M.
By Corollary 2.2, the conclusion of Lemma 6 is
equivalent to the assertion that
2.
"M
is of finite presentation".
Lemma 6 was really used in establishing equation
(1) in the proof of Lemma 1 above. Corollary 5.2.
Let
A
be a ring.
Then the equivalent condi-
tions of Theorem 5 are also equivalent to: (2.1)
The direct product of right flat, right A-modules,
is right flat. Proof:
Since
A
is flat as right A-module, condition (2.1)
implies condition (2) of Theorem 5.
We give two proofs of
the converse, one complete and one sketched. and let
Ni
Let
I
be a right flat, right A-module, for all
be a set i E I.
Proof 1.
Let
ring
Then by condition (1) of Theorem 5 we have that
A.
J
be a finitely generated left ideal in the
is finitely presented.
Therefore, all of
J
the left modules in
78
Section 6
the short exact sequence
o -+
J
-+
A -+
AI J
-+ 0
are finitely presented. functor:
Therefore, by Lemma 6, if we apply the
M'VV> ( IT N.) eM iEI ~ A
to this short exact sequence, the re-
suIting short sequence is isomorphic to the short exact sequence 0-+
IT
i E:I
(N. @ J) ~ A
IT
-+
i EI
(N. @ A) -+ IT (N. @ (A/J)) -+ O. ~ A i EI ~ A
In particular, we have that the mapping: (ITN.)@J-+ TIN. iEr ~ A iEI 1
is a monomorphism, for all finitely generated left ideals in the ring
A.
Therefore by Lemma 4,
IT N.
iEI Sketch of Proof 2. where
M and
N
J
is right flat.
1
By Lemma 6, given any monomorphism
f: M -+ N,
are left A-modules of finite presentation,
we have that (TIN.)®f
iEI
1
A
is a monomorphism.
But, using condition (3.3) of Remark 2
following Corollary 5.1, it is easy to see that every monomorphism in the category of left A-modules is the direct limit, overa directed set, of such monomorphisms every monomorphism have that (TIN.)@f i EI 1 A
f
f.
Therefore, for
in the category of left A-modules, we
Left Coherent Rings is a monomorphism of abelian groups. IT N. it:I
Remarks.
79
Otherewise stated,
is flat.
l
The elaboration of the sketched "Proof 2" above,
establishes another interesting condition that is equivalent to the conditions of Theorem 5.
Namely, that the ring
A
be
such that (4)
Given any monomorphism
there exists a directed set
D,
f: M -+ N
of left A-modules,
and direct systems indexed by the directed set 0,
of finitely presented left A-modules, and a map -;.(Ni)iED such that
(fi)iED: (Mi)iED
of direct systems indexed by the directed set f. :M. -+N. l
l
D,
is a monomorphism of left A-modules, for
l
lim M.'" M, lim N "; N, and such l iED i iED that under these isomorphisms lim f. corresponds to f. l iED
all
i E D,
and such that
Definition 2. A
Let
A
be a ring.
Then we say that the ring
is left coherent if it obeys the equivalent conditions of
Theorem 5.
(That is, any of the equivalent conditions (1),
(2) ,(3) of Theorem 5: or equivalently (3.1) of Corollary 5.1; or(3.2) of Remark 1 following Corollary 5.1: or (3.3) of Remark 2 following Corollary 5.1; or (2.1) of Corollary 5.2; or (4) of the Remark following Corollary 5.2).
Section 7 Denumerable Direct Product and Denumerable Inverse Limit
A be a category such that, for every sequence
Let i
an integer, of objects in
(as defined in [C.A.]) A
A,
the direct product:
Ai' IT A.
i E6' 1 Then we say that the category
exists.
is such that denumerable direct products of objects exist.
Also, if
A
is any category,
AW
then we let
denote the cateand for maps,
gory having for objects, all sequences (Ai)iE?"~ (B i )iE6"
is a map in
A,
all sequences for all integers
where
(f i )iE6'
f. :A.
~B. 111
i.
(This category can be interpreted as an "exponent category,"
C A ,
see section 3, Example 12,
for an appropriate category
Then, if denumerable direct products exist in the functor gory
A
"denumerable direct product":
A,
C).
then we have
AW'\l\,> A.
If the cate-
is also abelian, then it is easy to see.that this functor
commutes with fin. dir. prods. and kers., and that it is therefore a left-exact functor of abelian categories. functor
Therefore, this
is exact iff the denumerable direct product of a sequencE
of epimorphisms is always an epimorphism. Example 1.
If
A
is the category of abelian groups, then of
course the (denumerable or otherwise) direct product of epimorphisms is always an epimorphism. Example 2.
Let
S(X)
be the category of all sheaves of abelian
groups on a topological space
X, 80
where
X
is such that there
Denumerable Products and Limits exists a sequence of open sets
i
U1."
~ 1,
81
such that
n u,
i~l 1.
is not open (virtually every interesting topological space obeys this extremely mild condition).
Then
Six)
is an abelian
category such that denumerable (and even arbitrary) direct products exist;
but in the category
Six)
the denumerable
direct product of epimorphisms is not in general an epimorphism. (See [R.]).
A is an abelian category such that de-
Now suppose that
numerable direct products of objects exist and such that the functor,
"denumerable direct product":
Then, an inverse system
A
in the category (see [C.A.]), (n+2)
CJ.
,CJ.
ij
),
is exact. 'c._
1. , J '"6'
of objects and maps
j.::.i indexed by the directed set of integers
can be thought of as being a diagram:
CJ.
where
A = (A
i
(n+l)
>An+l
=CJ.
(n+l) CJ.
n+L n
n CJ. (n) )A _ _ _
--+ ...
for all integers
n.
Let us then define cO (A) Then let
dO
=c l
(A)
IT An. nEzr
be the unique map,
such that 'II
where
'II
n
:
0
n
dO
= CJ.
(n+l)
0'11
-
n+l
'II
n
,
is the projection.
Then if we define is a cochain
82
Section 7
complex in the abelian category
o
and
1.
A,
concentrated in dimensions
We sometimes denote this cochain complex more C*( (A ) ~).
specifically as H
O
(C*)
n n...,
~ 11 m
A
nEll canonically.
Then it is easy to see that
n
We define
Then Theorem 1.
Let
A be an abelian category such that denumerable
direct products of objects exist and such that the functor "denumerable direct product": AW'\)\,> A
is an exact functor.
Then given a short exact sequence of inverse systems indexed by the directed set
l',
(1)
there is induced an exact sequence in the category
A of
length six, Ij,m ' fn (2)
0->- (lim 'An)
~l'
nEl'
l (lim
1 lim <'An) nEt'
(liml "An) nEil' Proof:
---l»
11m "f ) (lim An) nEll nEl'
'fn
n
~(lim "An)~ nEil'
11ml "f n nEt' )(liml An) nEil'
)
0 •
Since the functor "denumerable direct product": AW'\)\,> A
Denumerable Products and Limits
83
is exact, we have the short exact sequence (1), from which we deduce a short exact sequence 0-> C* ( • A) -> C* (A) -> C* ("A) -> 0
(3)
A.
of cochain complexes in the abelian category
f- 0,1,
cochain complexes are zero in dimensions
Since these the Fundamental
Theorem of Homological Algebra (section 3, proposition 9) completes the proof.
Q.E.D.
From the exact sequence of six terms of Theorem 1, we deduce Corollary 1.1. Theorem 2.
The functor
Let
11ml nEI'
A be an abelian category obeying all the hypo(B n
theses of Theorem 1, and let
B
gers
n,
S (n))
be an inverse
nE?'
such that there exists an
A, and epimorphisms
in the category
all integers
,
A,
system in the abelian category object
is right exact.
such that
S (n+l)
0
Sn+l '" Sn 00
00'
for all inte-
n. Then
Proof:
Let
An", B,
the identity of
B,
all
n E?',
for all
and let
n E ?'.
be
Then
is an in-
verse system, and we have the epimorphism of inverse systems:
Since by Corollary 1.1, the functor
1
n~;
1
is right exact, to
complete the proof of the Theorem it suffices to prove that
84
Section 7
That is,we are reduced to proving the Theorem for a constant inverse system. dO: cO
->
cl
In fact, let
Then
is by definition the map such that Od O =
lTn
for all integers
a,
(n+1l
n.
olf
n+l
Since
-If
n
a,(n+l) =identity of
B,
this
simplifies to If
I claim that (Proof:
n.
for all integers
n
Replacing
dO A
is an epimorphism. that
A'
by any exact full subcategory
is a set, and is such that the denumerable direct product
A'
a sequence of objects in in
A',
and such that
as sume tha t
A
B
is a set.
A is an object
in the category
is in
A',
of
if necessary, we can
Then the functor
F,
V'VV>
IT Hom (V, ), vEA
A into
is a left-exact additive imbedding from the category
the category of abelian groups that preserves denumerable direct products--although it is not an exact imbedding. functor
F
Since the
is an imbedding, however, to show that
epimorphism it suffices to show that in the category of abelian groups.
F(dO)
(Yn)nE1' E IT An, nE1'
define
is an
is an epimorphism
Therefore, we are reduced
to proving the indicated assertion in the case that category of abelian groups.
dO
Then, given an element
A is the
85
Denumerable Products and Limits
x
I
0 + ••• + Yn-l YO
=
n
' -(Y- + ... +y ), l n
if
n = 0,
if
n > 0,
if
n < 0.
Then we see that
so that
dO
dO: cO (A*)
->
is an epimorphism, as asserted). c
l
(A*)
Thus,
is an epimorphism as asserted.
since the cochain complex
C* (A*)
But then,
vanishes in dimension
~
2,
we therefore have that liml An = HI (C*) = Cok dO = 0, nE;?' completing the proof. Remark.
Q.E.D.
It can be shown that Theorem 1, together with naturality
a
of the coboundary
(i.e., under the hypotheses of Theorem 1,
if we have another short exact sequence instead of
A's,
as in equation (1),
from (I') into (1); lim "An
d
Him
1
d,
'An
nE1
n
=> lim
l
'B
n
nE..,
is commutative), and Theorem 2, characterize the functor and the coboundaries Let
A
B's
together with a mapping
then the induced square about
nEf lim "B nE;?'
(I'), say with
a,
11ml, nE.;r
up to canonical isomorphism.
be an abelian category such that denumerable direct
products exist and such that the functor
"denumerable direct
86
Section 7
product" is exact.
Then it is not immediately clear whether
or not (P.2)
If
(An, C(n,m)
n,m E7 m
is an arbitrary inverse system such that the maps
epimorphisms, for all integers
n,m
with
are m
~n,
then the induced mapping
is an epimorphism. An abelian category such that denumerable direct products of objects exist and such that this condition holds will be said to obey the Eilenberg-Moore Axiom (P.2). Remark.
It is not difficult to show that (P.2)
implies that
the functor "denumerable direct product" is exact. Proof: integers
Suppose that i 2- 0.
all integers
f.:A.-+B. ~
~
~
are epimorphisms, for all
Define
n~O.
Then
n (C )
n2,O that all the maps are epimorphisms.
is an inverse system such By (P.2),
the map
n and CO", ITB. Q.E.D. lim C : ITA n~O n n~O n n~O In most applications ln the next chapter of this Introduc-
is an epimorphism.
But
tion, and in the rest of this book, we will rarely need this stronger axiom (P.2).
However, it will be used in a few re-
suIts of the Introduction, Chapter 2, sections 9 and 10.
87
Denumerable Products and Limits
In the Appendix to this section, we discuss in much more detail (much more than needed in the sequel)
the relationship
between the conditions discussed in this section.
However,
elsewhere in this text, the results of this Appendix will not be used.
Section 7
88
Appendix On The Eilenberg - Moore Axioms
We start by recalling some of the basic definitions in the paper of Eilenberg and Moore, in the first edition of the magazine "Topology", pages 1 - 24.
We refer to this reference as
"[E.M.l" in the Bibliography. We shall make use of the notions of "derived functors" and "satellites", concepts that will rarely be mentioned elsewhere in this book except in Examples and Remarks.
In particular,
the reader who does not have the background for this Appendix may omit it without incurring any difficultly. An abelian category such that denumerable direct products exist is said to obey axiom (P.O.).
If also the denumerable
direct product of epimorphisms is an epimorphism, then the category obeys axiom (P.l). Let
A be an abelian category such that denumerable direct
products exist (axiom (P.O».
Then the following conditions
are equivalent (this is easily deduced by arguments and constructions similar to those in [E.M.l):
(1)
Axiom (P.l) holds.
(2)
If
fi:Ai .... Bi
IIf.: IIA ..... lIB. ~
(3)
are epimorphisms, all
then
is an epimorphism.
~
~
i>O i>O
i>O
"lJ,ml"
the right satellite
i~O
i~O,
(in the sense e.g. of
89
Denumerable Products and Limits universal mapping properties) of the functor
"lim" i>O
exists,
"liml" i>O
" lim" i>O
and
is right-exact, and the two functors
"liml" i>O
together with their connecting homomorphisms are an exact connected sequence of functors. (3')
The right satellites (in the sense e.g. of universal
"lim" -
O
mapping properties) of the fun tor
exist and form a non-
negative cohomological exact connected sequence of functors, wi th the second satellite,
~im2 =: O. 1>0
(4)
There exists a right exact functor
gory of inverse systems of objects of
G,
A indexed by the non-
negative integers and maps of such systems, into "lim"
and
{to
G
that the functor
of
0
"lim", i>O
such that
and such
vanishes on constant inverse systems. be an inverse system of objects
A such that there exists an object
and epimorphisms ai+l,i
G
{Ai,aij)i,j~O
Let
and maps
A,
are part of a cohomological exact connected se-
quence of functors of length 2 starting with
(5)
from the cate-
ai:A...,. Ai'
all integers
ai+-1=a i , all integers i.:::.O.
i.:::. 0,
A
of
A
such that
Then, given any short exact
sequence of inverse systems (indexed by the non-negative integers) of objects and maps in
A,
starting with
(A. ,a .. ) . . 1
1)
0 '
1,),:::,
the resulting short sequence (of length three) of inverse limits is exact. When the above five equivalent conditions hold, then the right satellite
"liml" i>O
of
"lim" i>O
exists (e.g., in the sense
of universal mapping properties) and fits together with
"lim" i>O
to make a non-negative exact connected sequence of functors
90
Section 7
(where the functors in spots 2,3,4,5, etc. are taken to be (Ai,aij)i,j~O
zero functors); and, given any inverse system obeying the condi tion (5)
above, we have that
*m
1 · 1 A. = 0 • i>O ~ Notes 1.
G
When the equivalent conditions above hold, then given
as in condition (4), there exists a unique isomorphism (in
fact, a unique homomorphism) of connected sequences of functors (lim, liml) i>O i>O
(
of the funtor
2. (P.l»
~ (lim,
G)
such that
¢ = identity endomorphism
i>O
"lim". i>O
When the equivalent conditions above (i.e., axiom
hold, of course liml(A. ,a .. ) . . 0"" Coker(
ITA. ), i>O ~ ~J ~, J~ i>cr i>?
where
7Ti 3.
then let
0
¢ = ai+l,i
0
7T i + l - 7Ti '
When the above conditions (A. ,a. ,). ~
~J
'>0
~,J_
ai:A->A , i
A.
There exists an object all integers
all integers
i>
i > O.
(i.e., axiom (P.l»
hold,
be any inverse system of objects and
maps in the abelian category
Q)
for all integers
i ~ 0,
Suppose that either A
in
A
such that
and epimorphisms ai+l,i
0
a i + l = ai'
o.
For each integer
the map
a. 1 .:A. l->A. ~+,~
~+
~
is a split epimorphism of ob-
There exists an inverse system jects and maps in the category
A
an epimorphism of inverse systems:
®,
obeying condition (¢i).
~£.
O:(B.,e .. ). ~
~J
and
'>0'"
~,J_
Denumerable Products and Limits
91
(A. ,a .. ) . .
1
O. 1) 1,)::,
Then the following two conclusions hold: (a)
For each integer [lim A. 1 ->- A . i>O 1 J
and
(b)
Remark
lim i::,O
1.
1
j 2:. 0,
the natural mapping
is an epimorphism
A . '" O. 1
A obeys condi-
Suppose that the abelian category
tion (P.l).
If
(A.,ex .. ). '>0 is any inverse system of 1 1) 1,]_ objects and maps indexed by the non-negative integers in then it is easy to see that, in Note 3 above, condition for
(A.1 , a" . 0 1) ).1,)::,
are equivalent to conclusion (a) of Note 3. sion (b):
but even if
A
ai+l,i
Ai '" subgroup
and both
(2),
or con-
is an epimorphism, all integers
is the category of abelian groups, then
conclusion (b) of Note 3 does not imply this. AO = l' p I
Q)
(But not to conclu-
CD,
e.g., either of the conditions
elusion (a) imply that i ::. 0,
G),
is equivalent to condition
A,
p
i
• l' p'
i
~
0I
where
(E.g., take p
is any fixed
prime.
Then conclusion (b) of Note 3 above holds, even though
ai+l,i
is a monomorphism not an epimorphism, all integers
0
(Also, of course, condition than the other condi ti ons . g roups,
i
A.1 '" 'l'- /p 'l',
map, all integers
CD
G)
and
Remark
2.
i::. 0,
then
i
_>
0,
a.1+ 1 ,1. '" the natural
(A., a .. ). 1
1)
. 0
l,)~
of Note 3, but not condition
Let
(A., a .. ). . 0 1 1) 1,)2:.
in an abelian category that
A '" category of abe 1 i an
E . g ., if
all integers
of Note 3 is stronger
obeys conditions
(%)
of Note 3.).
be an arbitrary inverse system
A that obeys axiom (P.l).
is an epimorphism, all integers
i >
Suppose
o.
a condition apparently slightly weaker than condition
(This is
@,
or
Section 7
92 equi valently above).
CD,
or equivalently of conclusion (a), of Note 3
Then do (the somewhat stronger, equivalent properties)
condi tion
CD
of Note 3, equivalently condition
equivalently conclusion (a) of Note 3, hold? known in general at the moment.
Q)
of Note 3,
This is not
In [R.M.], an abelian cate-
A that obeys axiom (P.O) and such that this is always
gory
the case ("every inverse system (A .. ,a .. ) . . 0 lJ
lJ
l,J~
a + l, i '
non-negati ve integers, in which the maps
CD
epimorphisms, obeys condition obey axiom (P.2).
indexed by the
i
i
~
are
0,
of Note 3"), is said to
It is not difficult to show that when axiom
(P.l) holds, then axiom (P.2) is also equivalent to: (P.2 ')
Let
(A .. a .. ). l'
lJ
. 0
l,J~
be an inverse system of ob jects
and maps in the abelian category
A
epimorphism, all integers
Then if
lim A.
i>O
t-
i > O.
is an
such that AO t- 0,
we have that
O.
l
Another equivalent form of axiom (P.2) , under the hypothesis that axiom (P.l) holds, is (P.2").
(A. ,a .. ).
Let
l
. 0 lJ l,J'::'
be an inverse system of ob-
jects and maps in the abelian category
A
is an epimorphism, all integers
Then
liml A . l i>O
i > O.
such that
= O.
(For the proof that (p.2)
~
pg. 7 of [E.M.]). (Of course,
(P.2')
~
(P.2"), see Theorem 2.5,
(P.2)=;.(P.I)i
see page 86 above.)
All known abelian categories (e.g., the category of left A-modules, where (P .1) ,
A
is any ring with identity) that obey axiom
are easily shown to obey axiom (P.2) also (one veri-
Denumerable Products and Limits
93
fies, using elements, that any inverse system indexed by the non-negative integers such that the maps are all epimorphisms is such that conclusion (a) of Note 3 above holds). A
is any abelian category with enough projectives - or, weaker,
is such that
AEA,
that
then conditions (P.O),
A = 0 -
equivalent. A
(Also, if
HomA(p,A) =0,
Reason:
allprojectives
P,
implies
(P.l) and (P.2) are all
One first reduces to the case in which
is set-theoretically legitimate.
Such an abelian category
admits an exact imbedding into the category of abelian groups that preserves arbitrary direct products
(even arbitrary in-
verse limits indexed by arbitrary categories), namely the imbedding:
A~>n
Hom(P,A)). However, in most, but not quite PE A, P projective all, applications in this book, the strongest axiom ever needed is (P.'l).
Of course, the most important example, the category
of abelian groups, and also its dual category, obey these
all of
axioms, including (P.2).
Remark 3.
E.g., in the proof of Theorem l' of Chapter 2 of
Part I, below,
(and Theorem 2' in Remark 4 following Theorem
2 of Chapter 2 of Part I, below), axiom (P.l) is used.
Notice
also that we need that in the exact sequence of six terms
con~
structed in the proof of that Theorem (the exact sequence 1.8.1 of [P.P.W.C.]), the fourth object vanishes.
But this object
is (3)
, that ~s, t h e f unc t or
"1'*m, 1" i>O
applied to the inverse system:
94
Section 7
This inverse system clearly obeys condition above (where we take of
Note 3
n A = H (C*) ).
Q) of Note
Therefore, by conclusion (b) A
above, whenever the abelian category
axiom (P.l)
3
obeys
(which is all that we have assumed in, e.g., Theo-
rem I' of Chapter 2 of Part I and in Theorem 2' of Chapter 2 of Part I), then the object (3)
is zero, as required in the
proof. Remark 4. quired.
In Chapter 1 of Part I, even axiom (P.O) is not reAll that we need is that: "Denumerable suprema and in-
fima of sub-objects exist."
And, in fact, the barest minimum
condition is that "For the fixed integer
n,
the supremum of of
the increasing sequence of subobjects:
r ~ 0,
exists; and the infimum of the decreasing sequence of subobjects:
of
exists" .
It is easy to see,
using the exact sequences established in Lemma 1 and in Corollary 1.1 of Chapter 1 of Part I, generalized to arbitrary abelian categories, that the following condition is equivalent to this "bare minimum":
"For the fixed integer
creasing sequence of sub-objects of n H (C*)),
cise ti-torsion part of
i
~ 0,
Hn+l(C*))O (Im(restriction of
sion part of i
~
0, exists
Hn + l (C*))
-+
has a supremum; and (precise t-torsion
ti):
(precise ti+l-tor-
(precise t-torsion part of
Hn + l (C*))) ,
(so that one can speak of the t-divisible part of
the precise t-torsion part of Remark 5.
the in-
Hn(C*): t · Hn(C*) + (pre-
the decreasing sequence of subobjects, part of
n,
Hn+l(C*))".
The reader who is not congnizant with, or does not
like, abelian categories, may (totally) ignore this Appendix, and may read all Theorems (including e.g., Chapter 2 of this
Denumerable Products and Limits
95
Introduction and Parts I, II and III of this book), instead of, as occasionally being stated, for an arbitrary abelian category A
obeying specified axioms, only for the special case in which
A
is the category of all left modules over some ring with iden-
tity
A.
In fact, to date, I think that all special cases "of
practical use" (a term difficult to define, and a contention that some might debate, since some regard all abelian categories as being of interest - and certainly future applications at the "abelian category theoretic level" are even probable) of the Theorems, Propositions, etc. of this book, occur in this special case.
(However, it is perhaps instructive to understand things
at the more general level).
This Page Intentionally Left Blank
CHAPTER 2 THEORY OF SPECTRAL SEQUENCES Section 1 Spectral Sequences in the Ungraded Case
Definition 1.
A is an abelian category, then a spectral
If
A is:
sequence in the abelian category 1)
An integer
2)
A sequence where
phism of
E
r
Er in
rot; 71. indexed by the integers (Er,dr)r>r' - 0 is an endomoris an object in A and d r
A,
such that
d
r
0
d
r
all integers
'" 0,
A sequence (Tr)r>r' where Tr:H(Er,d r ) ~Er+l is an - 0 isomorphism in A, where H(Er,d ) =Ker(dr)/Im(d ), all inter r 3)
gers
r.:.. r o.
Such a spectral sequence is also called a spectral
sequence starting with the integer
rOo
sequence starting with the integer
rO
Clearly, every spectral can, by a translation in
indexing, be made to start with any other integer. is a spectral sequence starting (Er,dr,Tr)r>r - 0 is a specwith the integer r ' then clearly (Er,dr,Tr)r>r O
Also, if
-
tral sequence starting with the integer
r
l
,
I
for each integer
r l ,:::, rOo
Remark: category
Thus, intuitively, a spectral sequence in the abelian
A is simply a sequence of differential objects in
A,
such that each is isomorphic to the homology of its predecessor. be a spectral sequence in (Er,dr,Tr)r>r - 0 the abelian category A starting with Then we define
Definition 2.
Let
97
98
Section 1
for each integer two sequences
A,
~rO'
Zi (E ), r
each integer gory
r
r
~
by induction on the integer Bi (E ) r
r 0'
i
~
0,
identity of
E , r
Bl (E r ) = Im(d ) r composite:
from
all integers
First, define
E , r
~O,
for
and also a sequence of maps in the ca te-
"i-fold image",
integers
of sub-objects of
i
E + , i r
for all
r 2 r O.
Zo (E ) = E , r r
BO (E ) = 0, r
for all integers and
into
Zi (E ) r
"O-fold image" =
r2rO'
and
Zl(E ) =Ker(d ), r r
"I-fold image"
Zl (E ) -+ Er+l to be the r natural Ker(d r ) T Zl(E r ) =Ker(d r ) map >Im(d) ""r >E r + l , for r
all integers defined Ej+r
r~rO.
Zj (Erl,
If
B j (Erl
for all integers
into
Ei+r
we have defined the subobject
i
is an integer
and j
Zl (E ) r
of
such that
for all integers Zi (E r )
into
r
~rO'
Er+i
We call
Zi (E ) r
r.:: r 0'
j < i,
Bi -
Er'
and the map
-1
and all integers
By the inductive assumption, l
(E ), r
subobjects of
Er'
(Zi-l (Er+l))'
and define
"i-fold image" from
Zi-l (E r + l )
" (i-I) -fold image"
E , r
> Er ,
completing the inductive construction.
the i-fold cycles in
i-fold boundaries in r..::,rO·
~
into
Zj (Erl
to be the composite:
Z. (E )" I-fold image" l r " for all integers
0
and
(I-fold image)
and if we have
"j-fold image" from
as follows:
Zi_l (E r )
>2,
all integers
E , r i
and ~
0,
Bi (E ) r
the
all integers
Ungraded Case Remark 1.
99
Let
(Er,dr,Tr)r>r be a spectral sequence starting - 0 with the integer rO in the abelian category A. Fix an exact imbedding from
A (or, if
A that is a set and that contains
abelian subcategory of all
r> r ) - 0
and let cycle? u?
r
A is not a set, from some full exact
u E Er .
If
~
i
0,
then when is
u
an i-fold
And, when this is so, what is the i-fold image
Explicitly,
d r (u) = 0,
u
r ,
A~>A',
into the category of abelian groups, say
~rO'
E
U. l
of
is a O-fold cycle always; a I-fold cycle iff
in which case the I-fold image of
u
is the image
under the composite: an i-fold cycle (1)
u
is an (i-I)-fold cycle, and (2) if
fold image of
u
in
Er + i - l ,
then
in which case the i-fold image
U. l
d r + i - l (u) = 0 of
I-fold image of the (i-I)-fold image of case, then
u
u.
ui_l=dr+i_l(v) in E r + i - l for some vEE r + i _ l Let
the abelian category
(Er,dr,Tr)r>r - 0
integer (2)
j
~
0,
the map and that
E . r
is the (i-l)in
Er +i - , l
If this is the u E Bi (E » r
iff
(i.e., iff ui=O in Erri ).
be a spectral sequence in
A.
Then for every integer
as subobjects of
iff
is defined to be the
u
is an i-fold boundary (Le.,
Proposition 1.
u _ i l
(i ~ 0)
r >r
-
0
we have that
Also, for every integer
and every
we have that "j-fold image"
Zj (E ) .... E + r r j
is an epimorphism,
100
(3)
Section 1 (j-fOld image) (Z. (E » = Z. +' (E ) -1 1 r 1 ] r
!
(j-fold image)
all integers integer
-1
i,j,r
j.::. 0
(B i (E r » with
1
i,j :::,0,
and every integer
as subobjects of
'
= Bi+j (E r )
r :::.r ' O r.::. r 0'
Moreover, for every there is induced a
specific isomorphism: (4)
Z. (E ) /B . (E )". E
r
1
Proof:
]
r
r +"]
A is the category of abelian groups,
In the case that
the proof is by induction on bedding Theorem
[~J,
i
and is easy.
By the Exact Em-
the theorem follows for every abelian
category. Remark 2.
Let
(E r ,d r ,lr)r>r
with the integer
for each integer
we have that
Er
E
r+i
(Er,d r ) , E
r :::. rO
Remark 3.
A"
A'
C
r+l
Then since
= Ker
d r /1m d r '
is a subquotient
and each integer
is in a natural way a subquotient of
Therefore there exist unique subobjects with
A.
category
it follows that
r :::.rO'
Therefore for each integer
Er ·
i :::. 0, Er .
in
is isomorphic to the homology of
E r+l
of
rO
be a spectral sequence starting
-° the abelian
such that
Er+i
A'
= A"
•
A'
and
Explicitly
A" A'
of is
Let
be a spectral sequence starting (E r ,d r ,lr)r>r - 0 with the integer rO in the abelian category A. Then, for each integer
r :::. rO
in Remark 1 that definition of call it
and each integer
Er+i
is a subquotient of
'~ubquotien~'we
R . , r,l
from
i :::. 0,
Er+i
of the sequence of relations:
we have observed
Er .
Therefore by
have the natural additive relation, into
We can form the composite
Ungraded Case R
E
101
.
~> E
r+i
to obtain an additive relation from
E
r into itself.
r
It is
fairly easy to show that the domain of this relation is that the ambiguity is relation is Bi+l(E r ), Remark
Bi(E r ),
Zi+l(E r ),
that the kernel of this additive
and that the image of this relation is i~.O,
all integers
4.
all integers
r:=:.rO.
A be an abelian category, let
Let
Zi(E r ),
rO
be an inte-
ger and let
(Er,dr"r)r>r be a spectral sequence starting - 0 with the integer rO in the abelian category A. Then we have
AO
the dual category tral sequence in
O
A
in
",
A,
in
AO "
(E
Er
and
certain specific subobjects of
r~rO.
all integers O
A
in
object of
Er
r :=:.rO.
in
in
r
E
in
r
0
A
-
equiva-
A - for all integers
Explicitly, the "i-fold cycles of
and the "i-fold boundaries of
gers
E
is the quotient-object of
"
-1)
r' r " r
and the "i-fold boundaries of
lently, certain quotient-objects of i~O,
d
is a specr>r - 0 Therefore, by Definition 2, we have the
AO •
"i-fold cycles of
of
E
A: Er/Zi (E r ),
r
in
E
r
AO"
in
A:
is the quotient-
all integers
i:=:. 0,
all inte-
Otherwise stat;ed, under the operation of passing
to the dual category, and then replacing a quotient-object by the corresponding subobject, the constructions, Bi (E ), interchange. r daries in
Er
Zi(E ) r
and
(So, roughly speaking, the i-fold boun-
can be thought of as being the dual construction
of the i-fold cycles in
E
•
r'
all integers
We will say that an abelian category
i,r,
i:=:. 0,
A is closed under
denumerable suprema (respectively: infima) of subobjects iff whenever
A
is an obj ect in
A
and
Ai'
i :=:. 1,
are subobj ects
102 of
Section 1 A
then there exists a supremum (resp.:
ordered class of all subobjects of
A
ject in the abelian category jects of
A,
L A.
i>l
A.
in
and if
then the supremum (resp.:
exists, will be denoted Lemma 2.
A
(resp. :
infimum) in the A
i .::.1,
Ai'
is an obare subob-
infimum), when it
n
A.).
i>l
1.
If
1.
A be an abelian category such that denumerable
Let
direct sums of objects exist.
Then
A is closed under denumer-
able suprema of subobjects. Proof:
The reader will quickly verify that
e
1m «
Ai)
+
A)
is the required supremum.
i>l Corollary 2.1.
A
Let
be an abelian category such that denum-
erable direct products of objects exist.
A is closed un-
Then
der denumerable infima of subobjects. Proof:
By Lemma 2 applied to
AO,A o
is closed under denumerable
suprema of subobjects. Definition 3.
Let
A be an abelian category and let
(Er,dr,Tr)r>r be a spectral sequence in the abelian category - 0 A starting with the integer r O' Then for every integer r'::' r 0' we define (1)
r
co
subobjects of (2)
n Zi (E r ) if this denumerable infimum of i>O Er exists, and
Z (E )
B
(E co
subobjects of
r
=
) =
E
r
LB.1. (E r ),
i>O
if this denumerable supremum of
exists.
is called the permanent cycles of
E
•
r'
is called the permanent boundaries of
E
•
r'
all integers
Ungraded Case Proposition 3.
103
Let
(Er,dr,Tr)r>r be a spectral sequence in - 0 the abelian category A starting with the integer rOo Then for every integer
r
~rO'
we have that: exists, in which case,
exists iff
(1)
Zoo(E
r
under the epimorphism,
is the pre-image of
)
o
"(r - rO)-fold image": (2)
Boo(Er)
Z (E) r-r O rO
E
-+
B (E
exists iff
rO Boo(Er)
r )
exists, in which case,
00
Boo(Er)
is the pre-image of
under the epimorphism,
o "(r-ro)-fold image": (3)
If both
Zoo
and
Boo
exist as in conclusions (1) and
(2) above, then Er = Zo (E r ) Boo (E ) r
::::>
::::> ••• ::::>
for all integers every
r ':'rO'
Zl (E r )
r.
::::> ••• ::::>
Bi + (E r l
Zi (E r )
)::::>
And, when
the epimorphism
::::>
Bi (E r ) Zoo
Zi+l (E r ) ::::> ••• ::::>
and
Boo
::::> ••• ::::>
Bl (E r
)::::>
Zoo (E r )
::::>
BO (E r ) = 0,
both exist, for
"(r - rO)-fold image" induces an
isomorphism: Z (E
(4 )
00
rO
) /B (E 00
rO
)::;' Z (E ) /B (E ). 00 r 00 r
Proof:
By the Third Isomorphism Theorem applied to the epimor-
phism
¢ =" (r - rO)-fold image",
Z (E) .... E, r-r O rO r
isomorphism of ordered classes, from that contain
Ker ¢}
onto
we have an
{subobjects of
{subobjects of
E }. r
By the second
equation in conclusion (3) of Proposition 1, in the case
i = 0,
and the fact (from conclusion (1) of Proposition 1) that BO(Er) =0,
we have that
Ker ¢= B (E) . r-r O rO
¢-l(O) =B
r-r O
(E),
rO
Le.,
By equation (1) of Definition 3, Z (E 00
rO
) exists
104
Section 1
n
iff
Z.
i>O l+r-r O
(E)
rO
exists.
These are all subobjects of
(E) = Ker rp, and by the first r-r O rO part of conclusion (3) of Proposition 1, the subobject of Er Zr-r (EO)
o
that contain
B
corresponding to
n
Z.
i>O l+r-r O
is
rO
rp -1
clusion (1).
r
l
n
iff
(E)
which case
Z. (E )
(n
Z. (E
i>O l
)) =
r
E
C
Z. (E
i> 0
l
r
r
II Z. + (E) . i>O l r-r O rO
Therefore
•
) C E
exists, in
r
This proves con-
Conclusion (2) is proved similarly.
Conclusion
(4) then follows from the Third Isomorphism Theorem applied to the epimorphism:
( E ) -+ E. Finally, r-r O rO r conclusion (3) follows from conclusion (1) of Proposition 1 and
the fact that
"(r - r 0) -fold image": Z
Z (E ) =
'"
r
n
Z. (E ),
i>O l
r
B
'"
(E
r
)
=
lB.
i>O l
(E ).
r
be a spectral sequence in (Er,dr,Tr)r>r - 0 Then the abelian category A starting with the integer
Definition 4.
Let
Z (E ) and B",(E r ), '" rO 0 in the sense of Definition 3, both exist, in which case we de-
we say that the abutment
E",
exists iff
fine
From Proposition 3, conclusions (1), (2) and (4) we immediately deduce: Corollary 3.1.
Let
(Er,dr,Tr)r>r be a spectral sequence in - 0 the abelian category A. Let r be any fixed integer ':J o.
Then the abutment
E",
exists iff both
Z",(E ) r
and
B",(E ) r
exist, and when this is the case there is induced a canonical isomorphism:
Ungraded Case Remark 1.
Let
(1)
(E r ,d r
starting with the integer (E
(2)
d 1- 1 ) r' r' r r~rO
integer
rO
105
be a spectral sequence r )r>r - 0 rO in the abelian category A. Then ,1
is a spectral sequence starting with the O A .
in the dual category
From Remark 4 following
Proposition I, it follows that: (3)
Zoo(Ero)
Boo(Er)
"Ff
exists for (2) in the dual category
o
o
(E
00
in
rO O A ,
exists for the spectral sequence (1) in A iff O A
(call this
0
)")
in which case
'
BA (E 00
rO
i.e., quotient-object of
) E
is the sub-object of
rO
in
A,
Also (4) Z
(E 00
gory
B
rO
(E
)
exists for the spectral sequence (1) in
iff
rO
)
exists for the spectral sequence (2) in the dual cate-
O A
O
"z A
(call this
O
(E
00
the subobject of
rO
)")
'
E00
ZA (E
in which case
00
rO
)
is
i.e. , the quotient-object of
in
o zA (E ) = E /B (E ). in A, E 00 rO rO 00 rO rO tion 4, therefore imply that: (5)
A
00
(3) and (4), and Defini-
for the spectral sequence (1) exists in
A
iff
for the spectral sequence (2) exists in the dual category
E 00
AO,
in which case they coincide. Roughly speaking, it follows that the abutment
E
00
of a
spectral sequence in an abelian category is a "self-dual" concept, both in its existence and value; and that, in passing to the dual category and replacing quotient-objects by their corresponding subobjects, integers Remark 2.
Z
(E 00
r
)
interchange (all
r':' r 0) . Let
abelian category
be a spectral sequence in the r )r>r - 0 starting with the integer Then we
(E r ,d r A
,1
Section 1
106
have observed, in Remark 2 following Proposition 1, that a subquotient of of
E
r
,
Clearly
all integers
o
r
~
r
o.
Er
~Er+l
E
is
r
as subobjects
Then notice that, by Introductiol
Chapter 1, section 5, Corollary 1.4, we have that the subquotients ment
admit an infimum, iff the abut-
Er' Eoo
abutment
exists in the sense of Definition 4; in which case the Eoo
is that infimum.
Of course, this gives another
equivalent definition of the abutment
in terms of subquo-
E 00
tients. Definition 5.
Let
A
be an abelian category, let
rO
be an
(E r ,d r ,l r ' r >r
integer and let
and ('Er,'dr,'lr'r>r be 0 - 0 spectral sequences in the abelian category A starting with the same integer
rOo
Then a map of spectral sequences from
is a sequences into ('E r , 'dr' 'l r )r>r (E r ,d r ,l r )r>r (fr)r>r - 0 - 0 - 0 indexed by the integers r ~ r 0' where f is a map in the cater
gory
A
from
Er
into
'E r ,
for each integer
r
~
r 0'
such
that (MI) fr
0
d ; r (M2)
For every integer
r
~rO'
we have that
r
~
the diagram:
'd
r
0
fr
=
and such that For every integer
:~rrI--
r-+-l-'-'
r 0'
:rr.·drl
f Er+l-------------->'E r + l in the category Remark 1.
A
is commutative.
Given axiom (MIl, axiom (M2l is equivalent to the
107
Ungraded Case
statement that, for every integer
r
fr
by passing to the subquotients.
by
f
~rO'
fr+l
is induced by
Hence, if
(f r ) r>r is a - 0 is induced map of spectral sequences, then it follows that f r
Therefore a
by passing to the subquotients,
rO map of spectral sequences in the abelian category with the integer
A
starting
rO:
is completely determined by the initial map,
f
rO Otherwise stated, an alternative, equivalent, definition of a map of spectral sequences in the abelian category with the same integer ('Er,'dr"'r)r>r
-
exist maps
f
r
:E
->- 'E
conditions (MI) and Remark 2.
O
'
is:
0 r
r
into
from
such that there
"A map
for all integers
r
A starting
r .:::.rO + I
such that
(M2) above hold."
Suppose that
(Er,dr"r)r>r
o
and
are spectral sequences in the abelian category Suppose that
the same integer
A,
the abelian category
('E r , 'dr' "r)r>r
A
- 0 starting with is a map in
such that, for every integer
r .:::.rO'
induces a map fr:E r ->- 'Er by passing to the subquotients. rO (Z.(E »c:Z.('E ) (It is equivalent to say, "such that f rO 1 rO 1 r0
f
and
fr
(B i (E r » c: Bi ('E r
),
for all integers
i.:::. 0").
Then is
000 the sequence
(fr)r>r
-
necessarily a map of spectral sequences?
0
It is easy to see that the answer is, in general, "no".
Necessary
and sufficient conditions for such a constructed sequence (fr)r>r - 0 integers
of maps r .:::.rO'
(i.e., a sequence of maps, such that
f
rO
induces
fr
fr:Er->-'E
r
,all
by passing to
108
Section 1
the sUbquotients, all integers
r .:.r )' to be a map of spectral O sequences, is that Axiom (Ml) above hold.
A be an abelian category and let
Let
rO
be an integer.
Then we have the category Spec.Seq.
(A), having for objects rO all spectral sequences starting with the integer rO in the
A,
abelian category
and for maps all maps of such spectral
sequences as defined in Definition 5 above.
It is easy to see
that Spec. Seq.
(A) is an additive category, but in general is rO not abelian. (Of course, Spec. Seq. (A) is an additive subcaterO gory of the additive category having the same objects, and for
maps all sequences of maps
(fr)r>r as in Remark 2. This - 0 larger additive category, which is also in general not abelian,
is not very interesting, however).
i.:. 0,
For each integer
and
B. l
are covariant add i-
(A) into the category A. I f rO (A) (resp. : F' ,F") are the full subcategories of Spec.Seq. F rO generated by those spectral sequences such that Z"" (E ) (resp. : r
Spec. Seq.
tive functors from
o
(E
);
into
A.
B
r 0 Boo,E",,) 00
both
Z (E ) and Boa(Er» exists, then Zoo (resp.: "" rO 0 is a covariant, additive functor from (resp.: F',F") F
Proposition 4.
A be an abelian category, let
Let
rO
be an
integer, let
(Er,dr,Tr'r>r' ('Er,'dr,'Tr)r>r be spectral 0 - 0 sequences in the abelian category A starting with the integer be a map of spectral sequences from f=(fr)r>r - 0 (Er,dr'Tr)r~ro into ('E r , 'dr' 'Tr)r.:.ro· Then the following
rO
and let
two conditions are equivalent: 1)
2)
f
: E rO rO (fr)r>r - 0
is an isomorphism in the category A. rO is an isomorphism of spectral sequences.
->-'
E
Ungraded Case Corollary 4.1.
109
Under the hypotheses of Proposition 4, suppose
that the two equivalent conditions (1) and (2) of Proposition 4 Then
hold. If
Z (E 00
Zoo(E r
r 0
r
: E
-+ 'E
r
exists
)
and
)
o
f
r
is an isomorphism, all integers
(resp.:
If
o
)-+B ('E ); rO 00 rO an isomorphism in the category A. 00
by induction on
that
r
=
r 0'
fr
if
Zoo(f): Zoo(Er ) -+ Zoo{IEr ) o 0 resp. : Eoo(f): Eoo -+ 'Eoo) is
00
Proof of Proposition 4:
For
o
both exist), then
Boo(Er )
B (f): B (E
(resp. :
exists; resp.:
Boo(Er)
r,:: rO •
r,
r
(2)=> (1) is clear.
~ro'
we claim that
this is condition (l).
is an isomorphism.
isomorphism
H(f ). r
implies that
fr+l
Assume (1). fr
Then
is an isomorphism.
Suppose that
r,:: r 0
and
Then by Axiom (Ml), we have the
Then the commutative diagram in Axiom (M2) Q.E.D.
is an isomorphism.
Proof of Corollary 4.1.
The assignment:
(Er,dr,Tr)r>r ~>Er is a functor from Spec.Seq. (A) into A - 0 rO and therefore carries isomorphisms into isomorphisms. Therefore fr
is an isomorphism, all integers
r.
Also, since
is isomorphic to in {Er,dr,Tr)r>r - 0 Spec.Seq. (A), it follows readily that Z (E ) exists iff 00 r 0 rO If that is the case, then since Zoo ( I Er) exists.
o
(Er,dr,Tr)r>r ~>Zoo(Er ) is a functor on the full subcategory - 0 0 is an isomorphism F of Spec.Seq. (A), it follows that rO Q.E.D. in A. The other assertions are proved similarly. Remark 1.
In the statement of Proposition 4, suppose we weaken
the hypothesis, that
"(fr)r>r is a map of spectral sequences" - 0 to the weaker assertion, that " (fr)r,::ro obeys the hypotheses of Remark 2 following Definition 5."
Then the Proposition and
110
Section 1
"(f) " a s in r r~rO Remark 2 following Definition 5 induces a map from Zoo(E ) r
Corollary remain valid.
(Notice that an
o
into
Z ('E 00
and
E ). 00
rO
)
whenever both are defined; similarly for
B
00
Section 2 The Spectral Sequence of An Exact Couple, Ungraded Case
Definition 1. object in itself.
A
A be an abelian category, let
Let
and let
t:V -+ V
be a map in
V,
V,
V) = r
(Im(t ))r>O
a decreasing sequence of subobjects of
V.
then it is called the t-divisible part of
= n
of
V,
then it is called
Similarly, the sequence of subobjects,
V)
into
If a supremum exists
(t-torsion part of
(t-divisible part of
V
(Ker t )r>O
is an increasing sequence of subobjects.
the t-torsion part of
from
be an
r
Then the sequence of subobjects,
in the collection of all subobjects of
A
V
L Ker (t r ) . r>O of
V
is
If an infimum exists, V,
r Im (t ) .
r>O Definition 2.
On the other hand, we can consider the inverse
system, indexed by the positive integers, such that
i~l,
and such that
i>1.
If an inverse limit
t(i+l): v(i+l) -+v(i) lim(v(i),t(i))
V(i) =V,
is the map
t,
exists, then we
itl have the natural map:
The image of that map, a subobject of t-divisible part of
V.
V,
Finally, consider the direct system 1n-
dexed by the posi ti ve integers, such that t(i):V (i)
-+
V (i+l)
is the infinitely
is the map
t, 111
i> 1.
V (i)
= V,
i
~
I,
and
I f the direct limit of
Section 2
112
system should exist, then we have the natural map:
this direct
The kernel of this latter map is the infinite t-torsion part of V. Example 1.
If in the abelian category
A,
denumerable direct
products of objects exist, then both denumerable inverse limits and denumerable infima of subobjects exist. case, if part of in
t:V .... V V,
A.
is any map in
A,
Therefore, in this
then both the t-divisible
and the infinitely t-divisible part of
Similarly, if the abelian category
A
V, exist
is such that de-
numerable direct sums of objects exist, then denumerable direct limits and denumerable sups of subobjects exist, and therefore, t:v .... V
whenever
A,
is any map in
and the infinite t-torsion part of Example 2. in
AO,
object in
V
t:V .... V
be a map in
t:v .... V
and
V
exist.
A be an abelian category, let
Let
A and let
the t-torsion part of
A.
Then
V V
be an object
is also an
AO •
is also a map in
Therefore
we know what we mean by the t-divisible part, t-torsion part, infinitely t-divisible part, and infinite t-torsion part, of considered in
O
A
•
These are subobjects of
quotient-objects of
V
in the given category
V
O
in A.
A
,
V
i.e.,
It is easy to
see that, under the usual 1-1 correspondence between subobjects of
V
in
A
and quotient-objects of
the t-torsion part of
V
part of
A,
V
exists in
in
O
A
V
in
A,
that:
(1)
exists iff the t-divisible
in which case they correspond (under
the usual 1-1 correspondence between subobjects and quotientobjects of
V
in
A);
(2)
the t-divisible part of
V
in
AO
Exact Couple, Ungraded Case exists iff the t-torsion part of case they correspond:
V
113
exists in
A,
in which
(3) the infinite t-torsion part of
V
in
AO
exists iff the infinitely t-divisible part of
A,
in which case they correspond; and (4) the infinitely t-divi-
sible part of of
V
V
exists in
O
in
A
V
exists in
exists iff the infinite t-torsion part
A, in which case they correspond.
otherwise stated, if we replace quotient objects by their corresponding subobjects throughout, then in passing to the dual category, the notion of nt-divisible part" and nt-torsion part" interchange, and similarly "infinitely t-divisible part" and "infinite t-torsion part" interchange. Example 3.
If
t:V--V
is a map in the abelian category
and if both the t-divisible part of divisible part of
V
V
A,
and the infinitely t-
exist, then we always have
(infinitely t-divisible part of
V)c (t-divisible part
This is because, the infinitely t-divisible part of
V
of~.
is by
definition the image of the composite map:
V
V
and therefore is contained in
n Im(t ),
all integers
therefore the infinitely t-divisible part of in
n 1m (t n )
= (t-divisible part of
V
n':: 0:
is contained
V).
n>O Example 4.
If
t:V .... V
in the abelian category
is a map from the object A,
V
into itself
then Example 3 applied to the dual
category, using Example 2, tells us that, if the t-torsion part of
V
and the infinite t-torsion part of
V
both exist, then
Section 2
114 necessarily (t-torsion part of
V)
C
(infinite t-torsion part of
V).
Example 5. Proposition 1.
Let
A
be an abelian category such that denum-
erable direct sums exist and such that denumerable direct limit is exact.
Then if
t:V + V
is any map from any object
itself, the t-torsion part and infinite t-torsion part V
V
into
of
both exist, and (t-torsion part of
Proof.
V)
= (infinite
t-torsion part of
By Example 1, they both exist.
nite t-torsion part of
V).
By definition of "infi-
V", this latter is equal to
Ker (V (1) + it~ (V (i) , t (i) ) ) .
Since we are assuming that denumer-
able direct-limit is exact, we have that den. direct limit commutes with kernels. H~ Ker (V (1) + V (i) ) .
V(l)+V(i)
i l t - .
is
Therefore, this latter is equal to But
and the map
Therefore in this case (infinite t-tor-
r r V) = l-im Ker (t ). Since Ker (t ) are an increasing r>l sequence of subobjects of V, and since the denumerable direct
sion part of
limit of monomorphisms is a monomorphism in
A
(since denumerable
r l-im Ker(t ) is a subr>l r Ker(t ), r :: 1; and this
direct limit is exact) , i t follows that object of
V,
namely the sup of
latter is by definition the (t-torsion part of
Example 6.
Suppose that
and let
be an object in
V
Then explicitly:
A
V) .
Q.E.D.
is the category of abelian groups, A
and
t:V+V
be a map in
A.
Exact Couple, Ungraded Case (1)
(t-divisible part of
V)
=0
there exists an element (2)
n
EV
For every integer such that
(infinitely t-divisible part of a sequence
(3)
v
{v E V:
v n E V,
n
(t-torsion part of that
~
V)
0,
=0
115
V)
=0
t
n
(v )
=0
n
{v E V:
n, v}.
There exists
such that
{v E V:
3
an integer
n > 0
such
tn(v)=oO}.
These are, of course, all familiar concepts.
There are well-
known examples of cases in which the infinitely t-divisible part of
V
can be strictly smaller than the t-divisible part-
examples also appear, e.g., in Chapter 4, of this book. course, in the case of the category
A
Uf
of abelian groups, the
hypotheses of Proposition 1 in Example 5 hold, so that in this case (infinite t-torsion part of
V) = (t-torsion part of V).
(Of course, since we have seen in Example 2 that, in flipping to the dual category, and replacing quotient-objects by subobjects, that the concepts of nt-torsion" and nt-divisible" interchange, and also "infinite t-torsion" and "infinitely
t-divisibl~
interchange, it follows that, e.g., in the dual category of the category of abelian groups, that there exists an object
V
and
a map
V
is
t:V .... V
such that the infinite t-torsion part of
strictly bigger than the t-torsion part). Definition 3.
Let
A
be an abelian category.
graded) exact couple in the abelian category
Then an (unA
is a diagram
Section 2
116
(1)
in the category
A,
three corners. with maps
such that we have exactness at each of the
That is, it is a pair of objects, V,E,
t:V->-V,
h:V->-E
and
k:E->-V,
such that
together
Imt=Kerh,
1m h =Ker k, 1m k =Ker t. Proposition 2. gory V.
A, Let
d 2 = (h
0
If (1) is an exact couple in the abelian cate-
then let d =h k)
0
k,
0
(h
(tV)
0
denote
1m (t:V ->- V),
an endomorphism of
k) = h
(k
0
0
h)
is a differential object in
0
k =h
A.
0
E. 0
0
a subobject of
Then
k = 0,
so tha t
(E , d )
El = H (E, d) = Ker (d) 11m (d) .
Let
Then there is induced an exact couple, called the derived couple of the exact couple (1),
where the maps map
t,
"t",
l "ht- ",
and
"k" -1
the additive relation
rho r t
are induced from the ' and the map
k, respec-
tively, by passing to the subquotients. Proof. Let
tV
"t"
is a subobject of
and
t
maps it into itself.
denote the induced endomorphism of
is an additive relation from where defined. that
V,
dh = hkh = h -1
1m (r dh 0 r t ) = O.
Since 0
0
= O.
d =h
0
tV k,
into
E.
and since
tV.
r
0
h
(r
t
)-1
Clearly it is everyk
0
h = 0,
Therefore we have that
Therefore the addi ti ve relation:
we have
d (Imth
0
r~l»=
117
Exact Couple, Ungraded Case -1
rho r t
actually maps into the subobject
ker d
of
E.
There-
fore we have the everywhere defined relation induced by -1
rho r t '
from
tv
(Ker dllm d) = E . l
into
By diagram chasing,
I claim that the ambiguity of this additive relation from into
El
is also zero, and therefore that that relation comes
from a uniquely defined map:
tV -+ E . l
by using the Exact Imbedding Theorem category of abelian groups.
(In fact, we can assume, [~~J
that we are in the
The most general image of
under the relation is obtained as follows: such that in
t (v) = O.
Ker (d) 11m (d) = El
v=k(e),
dee) E Im(d), quired).
But, since
for some
l "ht- "
Therefore, Next,
is a map,
kl:Ker(d)-+V.
1m d c 1m h,
vanishes on the quotient,
eEE.
so the image of
k:E-+V
exactness of (1),
k
Choose any
t (v) = 0,
But then h(v)
h (v)
in
by exactness of
h(v) =hk{e) = El
is zero, as re-
is a well-defined morphism:
is a map; the restriction to
Ker(d)
Since
By
d=hok,
vanishes on
Therefore
k : El -+V. 2
into the subobject
v EV
and the image of
Imh.
Imdclmh. Therefore
and therefore the restriction
1m d.
0 E tV
is the most general image of zero under
(tV) -+E . l
on
h (v) E Ker d,
Then
the additive relation. (1),
tV
tV
of
kl
k
kl
of
vanishes k
also
defines a map by passing to
I claim that this map actually maps V
(In fact, we can assume, by
using the Exact Imbedding Theorem, that we are in the category of abelian groups. Ker(d),
then
keel
k(e) EKerh=Imt=tV,
Then we must show that, if is in
tV.
But
as required).
e EE
hk(e)=d(e)=O. Therefore
k
passing to the subquotients, a uniquely defined map as asserted.
is in Therefore
defines, by "k": El-+(tV) ,
Section 2
118
Therefore we have the diagram (2) of objects and maps in the abelian category three corners.
A.
It remains to show exactness at the
By the Exact Imbedding Theorem, this reduces to
the case in which
A
is the category of abelian groups.
Then,
it is proved by easy diagram chasing, which we leave as an exercise. Definition 4.
Let
A
be an abelian category, and let t
V
)V
\f
(1)
E
be an exact couple in the abelian category integer A,
r >0
A.
Then for each
we define an exact couple in the abelian category
which we call the r'th derived couple of the exact couple
(1), and denote: t
each integer
r >
o.
r
The construction is by induction on
r.
The zero'th derived couple of (1) is defined to be the exact couple (1). teger
r.:. 0,
Having defined the r'th derived couple for any indefine the (r + 1) 'st derived couple of (1) to be
the derived couple, as defined in Proposition 2, of the r'th derived couple of (1). Thus, explicitly, e.g.,
VO=V,
EO=E,
V =tV, l
Exact Couple, Ungraded Case El=(Kerd)/(Imd), is induced by by
k,
t,
where hI
d=hok,
119
to=t, hO=h, ht- l , and kl
is induced by
by passing to the subquotients.
kO=k.
tl
is induced
By induction on
r,
we
deduce Corollary 2.1.
A.
gory
Let (1) be an exact couple in the abelian cate-
Then for each integer
r
~
0,
the r I th derived couple
(lr) of (1) is such that
v r = try ' Er
a subobJ' ect of
is a subquotient of
and such that the maps
V, E, and
tr:Vr -+ Vr '
are induced, respectively, by the map,
rh
relation,
all integers
-r
0
r t :V-+E,
r > O.
d r = hrk r ,
where
Also,
t:V-+V,
and the map, k:E-+V EO = E,
and is such that
and d
r
0
k:E r r
-+-
V r
the additive respectively,
Er+l = Ker (d r ) 11m (d r ) , d = 0, all integers r
r > O.
The proof of this Corollary is immediate from the Proposition. Remark:
We might also picture the r'th derived couple of (1)
as:
where
II
til,
"h
0
t -r
ll
and
"k"
denote the unique maps induced
by passing to the subquotients by the map lation
and the map
k,
t,
the additive re-
respectively.
Also, worth
120
Section 2
recording by induction on
r,
Corollary 2.2. gory
Let (1) be an exact couple in the abelian cate-
and let
A,
(lr)
for each integer ( *) r
0
-<-
is
r > 0
be the r'th derived couple, r
~
Then
O.
we have the short exact sequence
[(Ker t) n (trV) )
~E r
.;x'[
r (V/Ker t ) ) t .(V/Ker t r )
in which the maps are the unique maps induced by
-<-
0
,
hand
k, re-
spectively, by passing to the subquotients. Proof.
From the r'th derived couple, as written in e.g. the
last Remark, we deduce the short exact sequence (2)
where
"k"
is deduced from
Again,
~rom
exactness of the r'th derived couple,
Cok (tr:V r -+ Vr) . fore
But
Vr
=
k
trV
by passing to the subquotients.
and
Cok (t :V -+ V ) = trV/tr+lv. r
r
tr
1m h "'-' r
is induced by
t.
There-
Therefore
r
(3) But, considering the map
tr:v-+v,
we see that
trV"'-'V/Ker tr.
Combining this with equations (2) and (3) gives the desired short exact sequence (*r). Remark:
The short exact sequence
(*r) of Corollary 2.2 is such
that, the objects at the right and left depend only on the endomorphism E . r of
t
of
V;
V
and
yet the object in the middle is
Therefore the sequence (*r) gives "a sort of computation" Er
in terms of
V
and
t.
(Of course, this computation is
not perfect, since it is only a short exact sequence.) Definition 5.
Let
Exact Couple, Ungraded Case
121
t
(1)
be an exact couple in the abelian category
A.
Then we asso-
ciate with the exact couple (1) a spectral sequence (Er,dr,Tr)r>O' category
A,
starting with the integer
as follows.
Let
Er
0,
in the abelian
be the object in the r'th
derived couple of (1) as defined in Definition 4, dr
=
hr
0
dr
0
dr
=
define
kr , 0,
r> O.
r> O.
Let
Then as noted in Corollary 2.1, we have that
and that
Er+l
=
Ker (d ) lIm (d r ). r
to be the identity map of
Er+l
Therefore, if we onto itself, then
is an (ordinary, ungraded) spectral sequence in the abelian category (Er,dr,Tr)r>O Remark:
A
starting with the integer
is the spectral
O.
sequence of the exact couple (1).
We have, for simplicity, constructed the spectral se-
quence to start with th·:! integer
O.
Of course, an (ordinary,
ungraded) spectral sequence can always be re-indexed to start at any other fixed integer
rO
if desired, videlicit
(E r - r ,d r - r ,T r - r )r>r o 0 0 - 0 The spectral sequence of an exact couple was first introduced in [E}::J. We now turn to computing the r-fold cycles, r-fold boundaries, permanent cycles and permanent boundaries, and eventually Eoo'
in the spectral sequence of the exact couple (1), in terms
of the given couple (1). quence starts with
First, notice that the spectral se-
EO = E,
ginal exact couple (1).
the "bottommost
object" in the ori-
Therefore, as in every spectral se-
Section 2
122
quence,
Er
is a subquotient of
Er = Zr (EO) /Br (EO)' and
Br(EO)
where
EO = E,
Zr (EO)
and as always,
is the r-fold cycles in
is the r-fold boundaries in
read off exactly which subquotient of
EO'
Therefore, to
E ( = E)
is
o
suffices to be able to determine the subobjects Br(EO)
of
E( =EO)
explicitly.
EO
E,
it
r
Zr(E ) O
and
The next theorem will do this.
First, we prove a lemma.
(1)
B,
of
f:A-+B
Let
Lemma.
Then
B , i E I, be an indexed collection of subobjects i l and let f- (B.) denote the pre-images, which are subLet
~
objects of of
A.
be a map in an abelian category
A,
for all
i E 1.
i <: I,
B , i
I f the subojbects
n B., then the subobjects iEI ~ admit an infimum, and in fact
admit an infimum, call it
B
i E I,
of
A
f-l( n B.) = n (f-l(B.)). iEI ~ iEI ~ Let
(2)
Ai'
i
E;;
I,
denote the images under i E 1.
I f the
Proof:
I
f (A.), ~
f (
2 A.)
(1)
Let
f (D) c B . i
iff
A,
iEI
iEI ~
f(D)C::B , i
all
f,
i E I,
Ai'
the subobjects of supremum,
be subobjects of
'i
iEI
Therefore, iEI,
n
iEI
f
-1
iff (B. l. ~
Dcf- l (
B, all
2 A. , among iEI ~ f (Ai)' i E I, admit a B,
and
f (A. ) • ~
be any subobject of
0
f (Ai)
admit a supremum,
then the images
iff
That is, among subobjects iEI,
which are subobjects of
among the subobjects of
=
A, and let
n B.l. itI ~
Dcf
-1
(B
i
),
A.
DCf-l(B.)
Then
for all
~
i E I,
f(D )c n B. iff iEI ~ of A, we have 0
Dcf
Otherwise stated,
f-l(
-1
iff
(nB.).
-1 iEI ~ Dc:: f (B ), all i
n
B.l
iEI ~
Exact Couple, Ungraded Case (2)
Let
A.ef-l(D).
0
be any subobject of
Therefore,
1.
A. e f- l (D)
o
Therefore, for all subobjects for all f (
i (;; I
iff
I
f(
f(Ai)eD
i E I,
A. e f-l(D)
iEI of
A.)eD.
iEI
t A.). iEI
I
iff
Then
for all
f (Ai) e 0,
i E I,
for all
1.
B.
123 iff
iff
iff
I
f (
A. leD.
iEI 1. we have that f (Ai)e 0
1.
B,
t
Otherwise stated,
f (A.) =
iEI
1.
1.
Q.E.D.
1.
Theorem 3.
A be an abelian category.
Let
Let
t
\}V
(1)
E
A.
be an exact couple in the abelian category
A
bedding from
(or from some "sufficiently large" full exact
A that is a set, and that contains the
abelian subcategory of
objects in (1), and the (t-divisible part of and the
(t-torsion part of
gory of abelian groups.
V),
Let
(1)
E = EO
(Er,dr,Tr)r>O
is in
Zoo(EO) (lr)
(2)
is in
Boo (EO)
be the spectral EO = E.
Let
e
be
Then:
exists, then the e E EO
is in the (t-divisible part of V). r'::' 0,
(t-torsion part of
manent boundaries, e E EO
k(e)
V)
an element
is an r-fold cycle, iff
I f the
into the cate-
exists, and in fact an element
For each integer i.e. ,
Zr (EO) ,
Zoo(EO)
iff
if it exist&
(using the exact imbedding).
If the (t-divisible part of
permanent cycles
V),
if it exists)
sequence of the exact couple (1), so that any element of
Fix an exact im-
Boo(EO),
V)
e E EO
is in
k(e) E trV. exists, then the per-
exists, and in fact an element
iff there exists an element
v
of the
124
Section 2
(t-torsion part of (2r) Br(E
o)'
ment
such that
For each integer i.e.,
v EV
Proof:
V)
r
~
h (v) = e.
0,
an element
e E EO
is in
is an r-fold boundary, iff there exists an ele-
such that
t
r
(v) = 0
and such that
h(v) = e.
We first prove (lr) and (2 ), for each integer r
r> O.
First, consider the short exact sequence (*r) of Corollary 2.2. We have that
Br(EO)CZr(EO)CEO=E,
The map
of (*r) is induced by
"k"
But the map
subquotients. (Ker t) if
n
(trV).
eE Zr(E )' O
e EE
Er
e EE
we must have that
Zr(EO)/Br(E O) =E r •
k:E +V
"k" maps
Therefore, if
must show that if
and
by passing to the
= Zr
onto
(EO) /B r (EO)
is an r-fold cycle, i.e.,
k(e) E trV.
is such that
Conversely, we
k(e) E trV,
then
e
is
an r-fold cycle. First, observe from the short exact sequence (*r)' and the fact that
"h"
is induced by
that it follows that such that
k (e) E trV.
h
Im(h) C Zr(E
by passing to the subquotient,
o).
To show that
Now suppose that e E Zr (EO)'
e EE
is
In fact, from
exactness of the upper left corner in the exact couple (1), we have that
t(k(e»=O.
Therefore,
k(e)E(kert)n(trV).
the exact sequence (*r)' and the fact that k
"k"
From
is induced by
by passing to the subquotient, it follows that there exists
e'EZr{E ) O
such that
k{e')=k(e).
Then
k(e-e')=O,
soby
exactness of the bottom corner in the exact couple (1), we have that
e - e' = h(v),
Therefore,
:3 II ~
V.
But recall that
e=e' +h(v) E Zr(E )' O
Im(h) C Zr(E )' O
as required.
Next, considering the short exact sequence (*r)' and noting that the map tient and that
"h"
is induced by
h
by passing to the subquo-
Er = Zr (EO) /Br (EO)' from the fact that
"h"
is
125
Exact Couple, Ungraded Case r (V /Ker t ) ] [ t· (V/Ker t r ) r must map Ker t
a map from
into
that
into
h
Since
"h"
Br (EO)'
all integers
r> O.
is a monomorphism, it follows more strongly that
Since by exactness of the upper right corner of the exact couple (1), we have of (2 r ),
it suffices to show that
e E Br (EO)'
fore
h (tV) = (ht) (V) = 0,
Then
e E Zr (EO) ,
of
e
makes sense.
of
e
is zero.
e E Ker k
=
to complete the proof
Br(EO)C 1m h.
In fact, let
and therefore the r-fold image
Since
the r-fold image
But then
1m h.
There-
Therefore
Br (EO) C 1m h
completing the
proof of (2 ). r Before proving (1) and (2) and thereby completing the proof of Theorem 3, we note that Theorem 3 can of course be written without reference to the Exact Imbedding Theorem.
So
written, it is Corollary 3.1.
Let
A
be an abelian category.
Let
t V
~
V
~/"
(1)
E
be an exact couple in the abelian category (Er,dr"r)r>O
A.
Let
be the spectral sequence of the exact couple (1).
Then (1)
If the (t-divisible part of
manent cycles
Zoo(EO)
V)
exists, then the per-
exists, and we have that
126
Section 2 Zoo (EO) = k -1 (t-divisib1e part of (lr)
(2)
For each integer
r
~
0,
we have that
If the (t-torsion part of
nent boundaries
Boo(EO)
V)
For each integer
r
~
0,
(1) and (2) of Corollary 3.1.
Theorem 3, take and (1)
A = E,
B = V,
Bi = the subobject
f = k, V,
of Lemma 1, if
exist in
V).
we have that
Completion of the proof of Theorem 3: forms
exists, then the perma-
exists, and we have that
Boo (EO) = h (t-torsion part of (2r)
V).
We prove the equivalent In the Lemma preceding I = {non-negative integers}, all
V,
i > O.
Then by part
i.e. , i f the t-divi-
n k- 1 (t i V) exists in E. But sible part of V exists, then i~l_l i by (lr) for r = i, we have that k (t V) = Zi (EO)' Therefore n k -1 (t i V) = n z. (EO) = Zoo(E O)' Therefore the permanent cycles i>l i>l 1 n k- 1 (t i V) =k- 1 ( n tiV), existsin Eo' -Also, by the Lemma, i>l i>l i.e., Zoo (EO) = k- 1 (t-divisib1e part of V). This proves (1) of the Corollary. Theorem 3, take A. = Ker ti, 1
Next, in the second part of the Lemma preceding A = V,
i> O.
B = E,
f = h.
I = {non-negative integers},
Then by the second part of the Lemma pre-
I Ker t i exists, ie., if i>O the (t-torsion part of V) exists, then I h(Ker til exists. i>O i But by (2r) of the Corollary with r = i we-have that h (Ker t )= ceding Theorem 3, we have that, if
i > O.
Therefore
Exact Couple, Ungraded Case Therefore the permanent boundaries exist in
Z h(Ker
Lemma, part of
l
til = h(
i>O
Ker t
i
),
Le.,
127
EO'
Also by the
Boo (EO) = h (t-torsion
i>O
V),
Note.
which proves
(2) of the Corollary.
Q.E.D.
In the course of proving Theorem 3 and Corollary 3.1,
we have actually proved some additional facts, which are worth recording. Corollary 3.2.
Under the hypotheses of Corollary 3.1, we have
that (lr)
k (Zr (EO»
n Ker
= (trV)
If the (t-divisible part of (1)
k (Zoo (EO»
V)
t,
all integers
r > O.
exists, then also
= (t-divisible part of
V)
n Ker
t.
Always, we have h -1 (B (EO» r
(2r) I f the
(t-torsion part of
(2)
h
-1
(Boo (EO»
Corollary 3.3.
Remark 1.
1 + tV.
= [Ker (tr:V ->- V)
V)
exists, then also
= (t-torsion part of
Under the hypotheses of Corollary 3.1, if both
The unusual thing in this is
thing between
V) + tV.
Boo(EO)
and
Zoo(E )' O
"Ker k = 1m h",
some-
a phenomenon that does not
occur in an "abstract" spectral sequence (as opposed to one that comes from an exact couple). trivial examples in which and
Boo (EO);
It is not difficult to give non-
lm(h)
is strictly between
and also examples in which
also examples in which
1m (h) = Boo (EO).
Zoo(EO)
1m (h) = Zoo (EO);
and
(Of course, if either
Section 2
128
Boo(EO)
or
Zoo(EO)
or both do not exist, then Corollary 3.3 re-
mains valid, if we simply delete the occurrence of or
"Zoo(E )" O
Remark 2.
"Boo(E )" O
or both, whichever or both do not exist.)
In Theorem 3, conclusion (1), and in Corollary 3.1,
conclusion (1), a sufficient condition for
"Z
is given, namely that the (t-divisible part of This result can be improved. conditions for
V,
0
V)
exists.
Namely, necessary and sufficient
to exist is that the decreasing sequence
Zoo(EO)
of subobjects of
to exist
(E )" 00
(Ker t)
And, when this is the case,
r ~ 0,
n (trV) , Zoo (EO)
have an infimum.
is always the pre-image
n «(Ker t) n (trV». A similar imr>O provement of conclusion (2) of Theorem 3 and of Corollary 3.1,
under
k
of that infimum,
is: Necessary and sufficient conditions for
Boo(EO)
that the increasing sequence of subobjects of r (tV) + [Ker (t : V -+ V) 1, is the case,
Boo (%)
r ~ 0,
to exist is
V:
have a supremum.
is always the image under
And, when this h
of this
L (tV) + [Ker (t r : V -+ V) 1) ) • r>O We take the next-theorem seriously.
supremum:
Theorem 4.
Boo
lEd
=
h(
Let t
(1)
be an exact couple in the abelian category (t-divisible part of exist.
V)
and the (t-torsion part of
Then, for the spectral sequence
exact couple (1), we have that short exact sequence:
A such that the
Eoo
(Er,dr"r)r>O
exists.
V)
both of the
And we have a
Exact Couple, Ungraded Case
n
0-<- [(Ker t)
(*)
(t-divisible part of
129
~E ~
V)]
'"
VAt-torsion part of V) ] 0 , ( t (VI (t-torsion part of V)} -
"h"
and
"k"
are induced by
hand
k
by
passing to the subquotients. Proof:
From conclusion (1) of Corollary 3.1 and conclusion (I)
of Corollary 3.2 we deduce the short exact sequence 0-<- [(Ker t)
(I)
n
Z",(E ) }inclusion} O where
"k"
"k II
(t-divisible part of
V}] <:--
Ker k -<- 0,
is deduced from
k
By Corollary 3.3 we have that
by restricting to subobjects. Boo(EO}clm h'=Ker k.
Therefore,
modding out the last two terms in the sequence (1) by the subobject (2)
h
Boo(EO},
we obtain the short exact sequence "k"
0-<- [(Ker t) n (t-divisible in
induces an
epimorphism from
3.1, conclusion (2),
V
Boo(EO}C 1m h.
sion (2), the pre-image of V) + tV.
V) ] <:---
B",(E O}
onto
E
j-nclusion '"
1m h.
By Corollary
By Corollary 3.2, concluunder
h
is (t-torsion in
Therefore, by the Third Isomorphism Theorem,
h
in-
duces a canonical isomorphism (by passing to the quotients) : (3)
[1m hlB", (EO)]
"h"
<: ""
(VI [(t-torsion in
V) + tV]} .
The latter object is canonically isomorphic to: V (t-torsion in V) ] ( t(V (t-torsion in V)} .
Substituting the isomorphism (3)
and this last isomorphism into the last term in equation (2) gives the short exact sequence (*).
Q.E.D.
130
Section 2
Remark 1.
We will call the rightmost group in the short exact
sequence (*), which is a subobject of
00
will be called the left
,
or sometimes the inverse part of
part of
the right part of part of
E
00
is a quotient of
is a subobject of
E 00
Remark 2. A,
E
The leftmost group
E 00 .
or sometimes the" direct part of in (*), which is a quotient of
the right part of
Eoo'
Notice that
E 00 •
and that the left
V,
V.
Let (1) be an exact couple in the abelian category
as in Theorem 4.
Then (1) can also be regarded as being an O
exact couple in the dual category
A
.
(Note that in re-inter-
preting the exact couple as an exact couple in the dual category, V,t,
and
E
change.)
retain their significance, but
hand
k
inter-
It is an easy exercise to see that the derived couple
AO,
induced by (1) in the dual category phic to the derived couple of (1)
is canonically isomor-
in the category
this latter is regarded as an exact couple in
A,
AO.
when
I.e., the
process of passing to the derived couple is a self-dual process. Therefore, likewise, the r'th derived couple of (1) considered in
O
A
(1) in
AO.
is canonically isomorphic to the r'th derived couple of A,
when this latter is regarded as an exact couple in
In particular, it follows that the construction of the
spectral sequence: A
(E r ,d r , l )r>O r
of the derived couple (1) in
is also self-dual; in the precise sense that, if one cons-
tructs the spectral sequence in couple in
AO,
O
A
of (1) regarded as an exact
then the resulting spectral sequence is canoni-
cally isomorphic to the spectral sequence in
A,
in
AO.
(E ,d r r
,l
r
)r>O
of (1)
when this latter is reinterpreted as a spectral sequence Since we have observed in the last section that the
131
Exact Couple, Ungraded Case construction of
Eoo
of a spectral sequence is also "self-dual"
in this sense, it follows that,
Eoo
the exact couple (1) in the category O
A
structed in
A from
constructed in A,
exists iff
Eco
con-
AO
from the exact couple induced by (1) in
exists, in which case they are canonically isomorphic. The reader will notice, most interestingly, that under the hypotheses of Theorem 4, in passing to the dual category the short exact sequence (*) is self-dual - that is, passes into an isomorphic copy of itself. have observed, is self-dual. left part) of
Eoo'
The middle
ter~
Eoo'
as we
However, the right part (resp.:
when re-interpreted in the dual category,
becomes the left part (resp.: right part) of sequence "turns around" under duality.
E . 00
That is, the
Thus, under the hypo-
theses of Theorem 4, the dual concept of the "right part" of Eoo
is the "left part" of
Remark 3.
Eoo'
and conversely.
The right part of
can be thought of as being
E 00
[V/(t-torsion)]/(mod t). For example, if
A is the category of abelian groups, or more
generally the category of right modules over some fixed ring then the right part of
Eoo
[V/(t-torsion)] where as
V
making
t
can be written as: 0 R, R[tJ
is regarded as right
t:V .... V,
and where
R
act as zero. [VI (t-torsion)]
R,
R[tJ-module by making
is regarded as left
Nt"
act
R[tj-algebra by
Another equivalent designation is Q
71.
Ji'[tj In the special case that
A is the category of all right mod-
132
Section 2
ules over a ring ter of
R,
element
R,
and if we have an element
such that the map
t:V'" V
t
in the cen-
is multiplication by the
t E R, then in this case the right part of
E",
can be
written as: [Vi (t-torsion)
J
~
(R/tR) •
R
Remark 4.
In general, if
an object in
A
and if
A
is an abelian category, if
t:V ... V
V
is
is a map, then for each inte-
. by the precise t r -torslon Eart 0 f V we will mean r.::. 0, r Ker (t ). Thus, by definition, the (t-torsion part of V) exists
ger
iff the increasing sequence of subobjects (precise tr-torsion part of
V),
r.::. 0,
has a supremum, in which case these coin-
cide. Notice, that, under the hypotheses of Theorem 4, the left part of V)
n
Em
can be
described as (precise t-torsion part of
(t-divisible part of
latter,
V).
{precise t-torsion in
Occasionally, we will call this V
that is t-divisible}.
From
the short exact sequence (*), we deduce corollary 4.1.
Under the hypotheses of Theorem 4, the following
several conditions are equivalent. (1)
(precise t-torsion part of
V)
(t-di visible part of
V) = {O} ,
(2)
The left part of
is zero,
(3)
E ~ [ vi (t-torsion) "':;. t· (Vi (t-torsion»
Em
]
n
,
the inverse of the isomorphisrr being induced by
"h"
by passing
to the sUbquotients. It should be noted that, e.g., if
A
is the category of
all modules over some Noetherian commutative ring
R,
and if
Exact Couple, Ungraded Case t
is an element in the center of
icle of
R,
then if
V
and if the map
t:V
V
and in the Jacobsen radis multiplication by
is finitely generated as R-module,
any non-zero divisible elements. conditions
->-
R
133
V
t,
cannot have
Therefore in this case the
of Corollary 4.1 hold, so that in this case the
right part of
is all of
E 00
E.
(Many textbooks on spectral
00
sequences make enough hypotheses to force conclusions (3) of corollary 4.1 to hold, as it does in a great many practical spectral sequences that one comes across.
However, in view of
the fact, observed in Remark 2, that the right and left parts of
Eoo
are dual to each other, this can never describe the
general situation.
(E.g., if under the hypotheses of Theorem
4, we have that the conclusions of Corollary 4.1 hold, then the right part of
E 00
in
AO
must vanish for the corresponding
exact couple to (1) in the dual category
AO,
and therefore
this dual couple cannot possibly obey the conclusions of Corollary 4.1, unless
E 00 = 0
(which is usually not the case)).
In
fact, as we shall see later, there is an interesting and important spectral sequence (although a graded one, see section 5) in algebraic topology, known as the Adam's spectral sequence, in which the right part of Eoo
Eco
vanishes, so that in this case
is isomorphic to its left part.
Remark 5.
In Remark 1 following Corollary 3.3, we noted that,
the unusual aspect in the conclusions of Corollary 3.3, was the existence of a canonical object,
Ker k = 1m h,
between
(As we noted, this unusual feature is a property only of couples.)
those spectral sequences that corne from exact
Since
Eoo= Zco(EO)/Boo(E )' O
this extra data is equiva-
134
Section 2
lent to giving a subobject of
Eoo'
Considering that the
rightmost map in the short exact sequence (*) is induced by it follows that the subobject of Im(h) ,
E
h,
induced by the subobject
00
is simply the right part of
E 00 .
(Therefore the short exact sequence (*) can be interpreted as containing all of Corollary 3.3). Remark 6.
In Theorem 3, Corollary 3.1, Corollary 3.2, and Cor-
ollary 3.3, we have assumed that the (t-divisible part of and that the (t-torsion part of
V)
both exist.
V)
All the re-
suIts of these three theorems, and also of Remarks 1-5 above, can be made to go through, if we assume the two weaker conditions listed in Remark 2 following Corollary 3.3, which, as noted in that Remark, are necessary and sufficient for both
Zoo(EO)
Boo(EO)
and
to exist (and therefore those two condiE '"
tions together are necessary and sufficient for
to exjst).
To recall the conditions:
Zoo(EO)
(C ) l objects of
V:
(Ker t)
Boo(EO)
(C 2 ) objects of
exists iff the decreasing sequence of sub-
n
(trV),
r ~ 0,
has an infimum; and
exists iff the increasing sequence of sub-
V: tV + Ker tr,
r ~ 0,
has a supremum.
When these
two conditions hold, then the short exact sequence (*) of Theorem 4 is replaced by the short exact sequence: (*)
o+[n
[vI[
r>O Whenever condition (C ) l
I
(tV+Ker tr)]]+o.
r>O (respectively:
(C » 2
fine the left part (resp.: right part) of
holds, one can de-
Eoo
to be the object
on the left (resp.: right) in equation (*) above. Thus: tion (C ) holds iff the left part of l
E 00
Condi-
(as just defined)
Exact Couple, Ungraded Case exists iff
Zoo(EO)
right part of
135
eixsts, and Condition (C ) holds iff the 2 (as just defined) exists iff
E 00
Moreover, Conditions (C ) l
and (C ) both hold iff 2
iff both the left and right parts of in the short exact sequence (*)
E 00
Boo(EO) E
exists. exists
'"
exist, iff every term
(just defined above) exists, in
which case we have the short exact sequence (*) above.
(Of
course, if the stronger hypotheses of Theorem 4 hold, then the "right part of
E",", "left part of
E","' and "the short exact
sequence (*)" as just defined above coincide with the
cor~es-
ponding constructions in Theorem 4.) Definition 5.
Let
A
be an abelian category, and let
(1)
and t' (2)
be exact couples in the abelian category exact couples from (1) and
f: E
->-
E'
If
A
into (2) is a pair
are maps in the category
t'og=got,
A.
h'og=foh,
A,
Then a map of
(g,f)
A
g:V-+V'
such that
k'of=gok.
is an abelian category, then the category
exact couples in
where
EC(A)
of all
is the category having for objects all
Section 2
136
exact couples in the abelian category of exact couples. abelia~
EC(A)
A
and for maps all maps
is an additive, but in general not
category.
If (1) and (2) are exact couples in the abelian category A,
and if
EC(A),
(g,f)
is a map of exact couples, i.e., a map in
from (1) into (2), then
couples.
Therefore
ditive functor from a map
(g,f)
(g,f) induces a map on derived
"derived couple" may be regarded as an adEC(A)
into itself.
By induction on
of exact couples also induces a map
the r'th derived couples,
r > O.
Therefore, if
r,
(gr,f ) r (g,f)
on
is a
map from the exact couple (1) into the exact couple (2) in the abelian category
A,
then there is induced a map from the spec-
tral sequence of (1) into the spectral sequence of (2).
Other-
wise stated, the assignment which to every exact couple (1) in EC(A),
associates the spectral sequence of the exact couple
(1), is an additive functor from
EC(A)
into Spec.Seq. (Al.
Section 3 Graded Categories
Definition 1.
Let
D
be an additive abelian group, the ele-
ments of which we will call degrees. ~
with degrees in the abelian
graded category) is a category (1) in
deg: Home (A,B) e,
deg (f
0
and
D
(or, more briefly, a D-
together with functions,
defined for every pair of objects
such that, whenever
g E Home (A,B) (2)
D,
-+
e,
Then a graded category
A,B,C
f E Home (B,C),
g) = deg (f) + deg (g)
are objects in
A,B
e,
we have that in the addi ti ve group
D,
and
such that (3)
For every object
exists an object lld :Ad
-+
A
e
in
e,
such that there exists a map
e
e,
and every degree
such that
and such that
lld
there
is an isomorphism
deg(lld) =d
"A D
with degrees shifted by
in
D.
dO.
is an additive abelian group, and if
category with degrees in the abelian group Definition L then for every map we mean
dE D,
Ad' in Axiom 3 of Definition 1, is, intuitively
speaking, If
in
in the category
in the category Remark:
Ad
A
f
in
e
D
(e,deg)
in the sense of
by the degree of
deg(f) ED.
An equivalent definition is as follows: Definition 1'.
Let
D
be an additive abelian group, the
elements of which we will call degrees. 137
is a
Then by a graded
f
138
Section 3
category
e
(1) of
graded
~
the additive abelian
~
0
we mean
A class, the elements of which are called the objects
e, For every
(2)
dE 0,
and every pair d Horne (A, B) ,
the giving' of a set, denoted
e,
d Horn (A, B),
briefly of degree
d
(3) pair
in
e
of objects of
or sometimes more
the elements of which are called the maps from
A
For every triple
d,d'
A,B
of degrees in
into
A,B,C
B, of objects in
e,
and every
the giving of a function:
0,
d d' Horne (B,C) x Horne (A,B)
-+
d+d' Horne (A,C),
called the composition. If
f
is a map of degree
a map of degree pair
(g,f)
d' from
B
d
from
into
C,
A
into
Band
A
under the function "composition" is denoted
into
is
then the image of the
(and is therefore by datum (3) above a map of degree from
g
go f
d + d'
C).
In addition, the data (1), (2), (3) must obey the following three axioms. (Existence of identity elements).
(4) A
e,
in
there exists a map of degree zero,
from the object are objects,
A
dE 0
map of
into itself.
e).
d
and
f oe A = f,
eA
e
o
A
E Horne (A,A) ,
into itself, such that, whenever
have that A
For every object
e
f E Horne (A,B) , A
0
g = g.
(e
A
d
g E Horne (C ,A),
Band
C
we
is called the identity
It is easy to verify from Axiom 4 that
is uniquely determined by Axiom
4, for all objects
(Also, if one dropped, in Axiom 4, the condition that
A
in e
A
is of degree zero, then one could deduce this property from the
139
Graded Categories rest of Axiom 4). ~
(5)
ssociative law of composition).
objects in
e
and
d, d' ,d" ED
g E Home (B, C)
and
d" hE Home (C,D),
d'
If
A,B,C,D
are d
are degrees and if
f E Home (A,B),
then ll
(h
g)
0
f = h
0
0
(g
0
f)
(Shift axiom).
(6)
in
Homg+d'+d (A,D). A
If
is an object in
dE D
is a degree, then there exists an object
maps
TJ
d
E Home (B,A)
d
and
, -d TJ_dEHOm e (A,B) where
ty maps of
B
into itself and of
B
and if in
e,
and
such that
and A
e
are the identi-
into itself, respectively,
as defined in Axiom 4. Definitionsl and l' are essentially equivalent: if
(e,deg)
group
is a graded category with degrees in the abelian
as defined in Definition 1, then for every pair of
D
objects
A,B
in
e,
d
e,
dE D,
and for every degree
define
Then the class of objects
Home (A,B) = {f E Home (A,B): deg (f) = d}. of
Namely,
together with the definition just posed of
for all objects
A, B
in
e
and all degrees
composition induced from the category
e,
dE D,
d Home (A,B)
and the
satisfy the condi-
tions of Definition I', and therefore are a graded category graded by
D
in the sense of Definition 1'.
Conversely, if abelian group
D
e
is a graded category graded by the
in the sense of Definition 1', that obeys the
additional axiom: (7) of degrees
For every pair of objects d,d' ED
such that
d d' Home (A,B) n HOP!e (A,B)
A,B
drid', =~,
in
e
and every pair
we have that
Section 3
140
then the graded category
C
graded by
in the sense of Defi-
0
nition I' comes, by the procedure of the last paragraph, from a uniquely determined graded category with degrees in sense of Definition 1.
Explicitly, given
C
in the
0
as in Definition
Hom (A, B) = U HO~ (A,B), for all C d(;D Then the class of objects of C, together
I' that obeys Axiom 7, define
objects
A,B
in
C.
with this definition of induced from
C,
HomC(A,B),
and with the composition
and with the obvious definition of for all
deg: HomC(A,B) +0,
A,B
objects in
C,
is the unique
D-graded category in the sense of Definition 1 that yields
C
by the procedure of the last paragraph. Remark:
Of course, technically, Definition I' is slightly
more general than Definition 1. abelian group
Namely, given a fixed additive
a graded category with degrees in
0,
in the
0
sense of Definition 1 is actually exactly equivalent to a graded category graded by
0
in the sense of Definition I' that obeys
the additional Axiom 7 above. graded category graded by
0
However, of course if
Cdisj ,
graded by
D
C
have the same objects as
c,
in the sense of DefiniNamely, let
and define
d d Hom d' . (A,B) = {d} x HomC(A, B) , all objects A,B in C l.S] degrees d ED. And take the obvious composition for
duced from
C.
Then of course
C
C
by another
tion I', that does obey the additional Axiom 7. disj C
is a
as in Definition I' above, and
fails to obey Axiom 7, then one can replace graded category,
C
and
disj C
c,
all
dis C j
in-
are canonically
isomorphic (for the obvious definition of isomorphism of "graded categories graded by the fixed additive abelian group Definition I').
Therefore every graded category
C
0"
as in
graded by
Graded Categories
o
141
in the sense of Definition l' is canonically isomorphic to
that obeys the additional Axiom 7, and therefore one Cdisj comes from a uniquely determined graded category with
0
degrees in
in the sense of Definition 1.
Hence, the two
concepts are essentially equivalent, and we shall often switch freely between Definition 1 and Definition 1'. Example 1.
Let
abelian group.
A
Then we define
0
by the abelian group lows.
The objects of
jects of
A
0
be any category and let AD,
be any additive
a graded category graded
in the sense of Definition 1', as folAD
d
are all families:
indexed by the set
D.
(A ) dED
of obe Given two objects (A ) eED
e
and (B) eED' and a degree dE 0, the maps of degree d from e e e (A leED into (B )eED are the indexed families: (f leED e e d+e ) , all e ED. We define the obvious where f E HomA (A , B composition using the composition in
A.
Then
category graded by the additive abelian group of Definition l' above.
We call the objects of
objects in the category
A
AD 0,
is a graded in the sense
AD
the graded
graded by the additive abelian group
0, or more simply the D-graded objects in the category we call category
AD A.
construction (1)
If
Three especially important special cases of the AD
are:
0 = (Z ,+), A.
then we have
AZ,
the category of
A z-graded object in
a singly graded object:
therefore,
AZ
A
0 = (Z
x
Z, +) ,
then we have
Z-
is also called
is also called the
graded category of all singly graded objects in If
and
the graded category of all D-graded objects in the
graded objects in
(2)
A;
AZxZ,
A. which we call
similarly the graded category of all bigraded objects in the
142
Section 3
category
A. More generally, if
(3)
n
~
then we have similarly
0,
n
A (~ '+),
the graded category of all n-graded objects in
A,
a graded category graded by the additive abelian group D =
n
(~n,+).
A,
graded objects in If
A (~,+)
(We sometimes call
D
if
n
the category of multi-
is understood.)
is an additive abelian group, then we will some-
times use the more brief term D-graded category in lieu of "graded category graded by the abelian group Example 2.
Let
Then define all
A
~n+d+l
0
gers
n.}
Then
abelian group (~-indexed)
(A*,B*) = {(fn)nE?: fn
An
into
fn = f n + l
0B*
0
Co(A) (~,+).
n
dA*
Bn+d,
all integers
A
gree
d"
n,
and such
for all inte-
is a graded category, graded by the Co(A)
is the ?-graded category of all
cochain complexes in the additive category d,
and for every pair
cochain complexes of objects and maps of
Hom~o(A)
A,
is a map in the
Hom (An,B n + d + l )
i~
(Notice that, for each integer
of
(~,+).
cochain complexes of objects and maps in
A from
that
D=
the ?-graded category having for objects
Hom~O(A)
and such that category
be an additive category and let
Co(A),
(~-indexed)
D".
(A*,B*)
A,
A. A*,B*
of
that the elements
are the "maps of cochain complexes of de-
in the usual sense).
Notice, 'in this case, that i f
A* E Co (A)
and
is a degree, then an example of a cochain complex
dE 7! A*
that sat-
d
isfies the conclusions of Axiom 6 of Definition I' is the cochain complex
A*
the coboundaries
d
such that dn * = d n+d A*, Ad
with degrees shifted by
all all
n E ~.
n E ~,
and with
Clearly, this is
d", perhaps justifying the Re-
"A*
Graded Categories
143
mark following Definition 1. Example 3.
If
A
is an additive category, then we define a
(~ x~,+)-graded
category, which we denote
(~x~,+)-graded
category of double complexes of objects of
The objects of maps in
A:
D(A)
and call the A.
are all double complexes of objects and
that is, all doubly indexed families:
(AP,q'd~i:o),a~O:l)) (p,q)E~x~ dP,q
D(A),
. AP,q -+-AP+l,q
and
(1,0)'
where
aP,q
AP,q
is an object in
. AP,q -+-AP,q+l
(0,1)'
A,
are maps in
p,q _ 0 "p,q+lo "p,q _ such that 0(1,0) 0 d(l,O) - , 0(0,1) 0(0,1)-0 and p+ 1 I q "p, q _ p, q+ 1 "p I q d(O,l) 0 O(l,O)-a(l,O) 0(0,1)' all integers p,q. If
A
,
"p+l,q
0
and
B**
are two such double complexes, then for every pair of
integers
d,d',
A** into
B**
be:
A**
{(fP,q)
: fP,q AP,q -+- BP+d,q+d' (p,q)Eilxil' ,
A,
category
we define the maps of bidegree (d,d') from (d,d' ) (Le., the elements of HomD(A) (A**,B**}) to
all integers
p,q,
is a map in the
such that in
Horn (AP,q BP+d+l,q+d') A' ,
in
Horn (AP,q,BP+d,q+d'+I),
and such that dP+d,q+d'
0
fP,q
(0,1)
all integers D(A)
= fP,q+1
p,q}.
0
aP,q (0,1)
Then, with the composition induced from
is a graded category, graded by
~ x~.
It is the
~x~-
graded category of double complexes in the additive category Notation:
In a
(~x~)-graded
A,
A.
category, by the bidegree of a map
we mean simply the degree of the map, in the sense of Definition 1.
Example 4, integer
> O.
Let
A
be an additive category and let
n
be an
Then an n-ary complex in the additive category
is an indexed family:
A
Section 3
144
for every
n
(PI, ... ,Pd~zr,
and for every PI,···,p a. n
Pl'···'p A n
(PI' .•. , P n ) E: zrn
and every integer
is a map in the category
1
Pl,···,p· I,P.+I,p·+I,···,p A 11 1 n, Pl,···,p· I,P.+I,p·+I'···'P a. 11 1 n
is an object in
A
i,
A, I 2 i 2 n,
PI,···,p A n
from
into
such that 0
PI'···'P a. n= 0
1
in
1
HomA(A
PI'···'P
(PI' .•. 'P n ) Ezr
n,A n
Pl,···,p· I,P.+2,p·+ I ,···,p 11 1 n) and all integers
i,
12i2n,
for all and such that
a.PI'··· ,Pn 1
PI'··· ,P
a.
J
n
in
Pl,···,p Pl,···,p· 1,P.+l,p·+l,···,p· 1,P.+I,p·+l,···p HomA(A n,A 11 1 ]J J n), If
whenever B*···*
are n-ary complexes in the additive category n
(e l , ... ,en) E zr, A*···* (f
A*···*
into
then a map of multidegree
B*···*
A,
(e ,.·· ,en) l
and and if from
is an indexed family:
PI' ... 'P n )
n, indexed by zrn where (PI'··· ,Pn)Ezr PI,···,p PI,···,p Pl+el, .•• ,p +e f n A n .... B n n is a map in A, all Pl+el,···,p +e Pl,···,p (PI' ... ,P ) Ezrn, such that d n no f n n i PI,···,Pi-I,Pi+I,Pi+I,···,Pno Pl,···,Pn n f a i ' all (PI' ... , P n ) Ezr , all integers i, I ~ i ~ n. Then, for each fixed positive integer n,
the class
category (el, .•• e n )
A,
Mn(A)
of all n-ary complexes in the additive
together with the maps of multi-degree just defined for all
vious composition induced from
A,
is a graded category with
Graded Categories n (7 ,+)
degrees in the abelian group
This is the
I' .
~
n
in the sense of Definition
-graded category of all n-ary complexes in
the additive category Notation:
145
A,
Given a map in a
which we denote by ~
n
M (A).
n
-graded category in the sense of
Definition I, by the multidegree of the map we mean the degree of the map as defined in Definition 1. (Of course, Examples 2 and 3 above are the special cases of Example 4, in which
n =1
or
2
respectively; where, e. g. ,
in identifying Example 3 with the special case
n =2
of Example
4, we are making the notational identification: ~p,q
01
"p,q = "p,q °(0,1) °2 '
'
Example 5.
Let
D
a
11' t
1n egers
p,q.
)
be the trivial additive group
D = {O}.
Then of course the notion of "graded category graded by
{OlIO
is equivalent to that of "category" in the usual senSe([C.A.
n. This
example shows that the notion of "graded category" can be interpreted as a generalization of that of "category". Remark:
In general, given a graded category graded by the
additive abelian group n
D = ~ ,+);
(~xZ ,+);
or
~n ,+)
where
is a non-negative integer, we will sometimes call such a
graded category a singlY graded category; a biqr!ded category; or an n-graded category, respectively.
(Thus, in Example 5
above, it is noted that the notion "O-graded category" and the usual notion of "category" essentially coincide). D=
~/2Z,+),
Example 6.
Let
order two.
Then certain D-graded categories are occasionally
considered in mathematics. we have gory.
A (~/21)
the additive cyclic group of
E.g., if
A is any category, then
as defined in Example 1, a
(~/2~)-graded cate-
A special case of this is the one in which A = {abelian
146
Section 3
groups}.
If
X
is a base pointed topological space, then the
usual complex K-functor evaluated at two.
Therefore
K
X
is periodic of period
can be regarded as a contravariant functor
from the category of base pointed topological spaces and homotopy classes of maps into the underlying category (in the sense of Definition 1) of the (;;?/2iZ")-graded category tor spaces} ;;? /2:i.
Of course, f or every con t'lnuous b ase pOln ' t-
preserving function degree zero.
f,
e.g., if
cal space such that
t-
0,
we have that
K
1
(X)
t-
then" cupping with
in the
K(f)
is a map of
C
of
However, there are interesting maps of degree one
in complex K-theory:
u
C={complex vec-
(~/2:i)-graded
X
and i f
0,
u"
is any base pointed topologiis such that
is a non- zero map of degree +1
category
C
from
K(X)
into itself.
The notion of "graded category with degrees in an additive abelian group" as in Definition 1 above, and also Definition l' above, are original to Birger Iversen of the University of Aarhus. Let group
C
D.
"deg",
be a graded category with degrees in the abelian
Then, by Definition I, if we ignore the function
C
is also an (ordinary) category (without grading).
The category
C
has a natural subcategory, which we denote
CO'
and call the category of maps of degree zero of the D-graded category
C:
Namely, take for
objects the objects of zero in C.
(CO
C,
Co
the category having for
and for maps, all maps of degree
o
(A,B) = Hom (A,B), all objects A,B in C C o is of course an ordinary category, without grading).
C.
Thus,
Proposition 1. belian group
Let D
Hom
C
and let
be a graded category graded by the aA
and
B
be objects in
C.
Let
147
Graded Categories dE 0,
and choose
n_ : A_ -+A d d
an isomorphism in
(by Axiom 3 of Definition 1).
-d
e
of degree
Then there is induced a spe-
cific 1-1 correspondence between the set of all maps of degree d A_
from
A
into
into
d
Proof:
B,
and the set of all maps of degree
0
n_d
g -+ g
0
(n_
d 1-1 0 Hom (A,B) ---t~ Home(A_d,B). e on 0
B:
is such a bijection, with the inverse function: )
d
-1
•
In general, if belian group degree
dE D,
Definition 1.
e
with range
d,
We call
A,
e
and every
Ad'
and an iso-
as in Axiom 3 of
call it Ad'
in
the object
A
fixed isomorphism
with degrees shifted
nd: Ad .... A
the shift isomorphism (of degree
all objects
Definition 2.
A
let us fix an object, call it
and the
d,
is a graded category graded by the a-
then for every object
0,
morphism of degree
A),
from
In fact, by Axioms 2 and 3 of Definition 1, the function:
f .... f
2Y
0
A
Let
in 0
e,
all degrees
of degree d
with range
dE D.
be a fixed additive abelian group.
an additive graded category indexed
2Y
d
Then
the abelian group
0,
or
more briefly, an additive D-graded category, is
(1)
D,
A graded category
e
indexed by the abelian group
together with (2)
The structure of additive abelian group on
for all objects
A
and
B
in
e
and all degrees
d
Home(A/B) dED ,
such
that (3)
Whenever
A,B,C/D
are objects in
e,
d,d' Id" E 0
are degrees and f and g E Hom~ (A, B) are maps of the same degd' d" and k E Home (D/A) then we have that ree I h E Hom e (B I C) h
0
(f + g) = h
0
f + hog
in
d+d' HOme (A/C)
148
Section 3
and (f
+ g)
If
C
k = f
0
0
k +g
Hom
in
k
0
d+d" C
(D,B) .
is an additive graded category with degrees in the
abelian group
D,
C,
ree zero of
Co
and if
then clearly
is the category of maps of deg-
Co
is an (ordinary, ungraded)
additive category. In addition, by Axiom 3 of Definition 2 (the distributive laws) we trivially have that
(*)
If
A
category dE D
and
B
if
C,
are objects in the additive D-graded
f,g: A-+B
are maps of degree
if
is any degree and if
the shift isomorphisms of degree
B
0,
d
with ranges
A
and
respectively, then in
A converse of this observation is true, which can be used to characterize additive D-graded categories the graded category structure on
C
Co
Co
(ignoring the
Namely,
Proposition 2.
C
in terms of
(ignoring the addition)
and of the additive category structure on grading).
C
Let
D
be an additive abelian group and let
be a graded category graded by the abelian group be the category of maps of degree zero of
an (ordinary) category (without grading). given additive binary compositions all objects
A,B
Co
Then
Let
Co
is
Suppose that we are on
in the (ordinary) category
(ordinary) category
C.
D.
Hom
Co
Co
(A,B)
for
such that the
becomes an (ordinary, ungraded) addi-
Graded Categories
149
tive category, and such that Whenever
(*)
and
d
A,B
is a degree in
B)-l ( Tld
0
(f + g )
0
D
f,g E Home (A,B)
CO'
are objects in
o
we have that
A = '(ndB)-l Tld 1
0
f
0
A + (B)-l T]d Tld
g
0
A T]d
0
Then there exists a unique way of introducing
in
d
additive binary compositions on and all degrees
dE D,
A,B
for all
Homc(A,B)
c
in
such that the D-graded category
C
be-
comes an additive D-graded category, and such that the thereby induced structure of additive category on one,
Co
is the prescribed
C }.
o
Proof:
First, let us prove uniqueness.
If we have any collecd
tion of additive binary compositions on the that the graded category
C
with degrees in
ditive graded category with degrees in induced addition on (+AB)ABEC ,
,
0
'
Co
then:
Hom (A,B) 's
D,
D
such
becomes an ad-
and such that the
yields the given additive structure If
dED,
A,BEC
and
d
f,gEHomC(A,B),
by the distributive law (Axiom 3 of Definition 2) we must have (1) However, on the right side of equation (I), since
pends only on the additive structure of in
A
and d are of degree zero, the right side of equation (1) de-
A gO T]_d
C.
Co
f
0
Tl_
and the composition
This proves uniqueness.
Next, let us notice that, although the hypothesis (*) depends
~
priori on the choice of elements
an isomorphism of degree all degrees
dE D,
d
with range
A Tld A,
such that for all
A Tld
A E A,
that actually condition (*) will hold for
is and
150
Section 3
one such set of choices iff it holds for any other. claim that if (*) holds, if
A,B t;; C,
f,g E Home
resp.:
degree
o
d
(Proof:
and if
(A,B),
with range
A
-1
L
-1
(f+g}n=L
B -1
[(nd)
A,
w,
dE D
and if
is any isomorphism of
B,
respectively
then
There exist unique isomorphisms of degree zero
such that n = nd w
n,
if
I.e., we
-1
0
e,L
Then
e,
B -1 A -1 B -1 A B -1 A (n d ) (f+g)nde=L rInd) fnd+(n ) gn ]8= d d
A
fndJe+l
-1
B -1
rInd}
A
gndJe=w
the last equality holds since
Co
-1
fn+w
-1
(The next-to-
g6.
is an additive category; the
equality before that fo11ows'from (*}}). Next, let us prove existence of the indicated additive structure on
C.
If
A,Bt;;C,
d
and
dE D
f,g E HOme (A,B) ,
then
define (2)
Then by Proposition 1,
d
Home (A,B)
becomes an additive abelian
group with this definition of addition.
To complete the proof
of the Proposition, it is left to verify Axiom 3 of Definition 2. First, notice that, by the hypothesis
(*), the definition
of sum, equation (2), is identical to the definition of sum: (3)
(Proof:
By (*), applied to the maps,
and to the isomorphisms of degree have that
-d,
B -1
(nd)
A n-d
f
and
and
B -1
(n d )
B -1 (nd) ,
g, we
Graded Categories
151
B [ (nBd) -1 0 f + ( B) -1 ] A B (B) -If A B (B) -1 A lld 0 'I lld 0 9 0 ll_d = fld 0 lld fl_ d + lld 0 fld 9fl_ d · The latter is clearly equal to
A
Composing on the right with side of equation
(ll_d)
-1
,
we obtain that the right
(3) equals the right side of equation (2), as
required) .
o
Next, suppose that where (4)
A,B,D E e,
d
t:;
D.
d
and
f, g E Horne (A, B)
hE Horne (D,A) ,
'rhen we claim that
(f+g) oh=foh+goh.
In fact,
8 = (ll~d)-l
let
morphism in such that
e
of degree
h = hO 0 8.
A
and
hO = h 0 ll_d. and
hO
[(f + g)
0
d
Then
8
is an iso-
is a map of degree zero
And
(f+g) oh= (f+g) 0 (hOo8)
ho]
8
0
But, by equation (2), f 0 h + 9 0 h = [f 0 h8
-1
+ 9 0 h8
-1
] 0 8 = [fh
o + 9h O]
These two equations imply equation (4), when both of degree zero.
d
Next, let
f,gEHome(A,B),
and
dE Dare arbitrary, and let
and
d' E D
tha t
f 0 8
is arbitrary.
f
0 8 and
are
where
A,BEe
d'
hE Horne (E ,A), where
Then choose an isomorphism
is of degree zero.
9
Then also
g
zero, so by equation (4) applied to the maps
0
8
8
such
is of degree
f 0 8, 9 0 8,
have: (f + g) 0 h = (f 0 (88- 1 ) + go (88- 1 »
EEe
0h =
[(f8) 08- 1 + (98) 08- 1 ] 0 h= [(f8 +g8) 08- 1 ] 0 h=
we
152
Section 3 [fe + ge) [f
0
0
(ee- l )
(6- 1 h) = [(fe) 0
h) + [g
0
0
(e-lh)) + [(ge)
(ee- l )
0
0
(e-lh))
h) = fh + gh.
This proves one of the two distributive laws; the other is proved similarly. Remark:
Q.E.D.
Proposition 2 implies that, if
C
belian group, and if additive abelian group so that
C
0
is an additive a-
is a graded category graded by the 0,
then to introduce an addition on
C
becomes an additive D-graded category in the sense
of Definition 2 is exactly equivalent to introducing an addition on the
Co
(ordinary, ungraded) category
(consisting of
all objects, and of all maps of degree zero, in
Co
C),
such that
becomes an (ordinary, ungraded) additive category in the
usual sense, and such that condition (*) above holds.
There-
fore, an alternative equivalent definition of "additive graded category" is: Definition 2'.
Let
0
be an additive abelian group.
additive graded category with degrees in
0
A graded category
(2)
An additive binary composition on all objects
A,B
is:
C with degrees in
(1)
in
ungraded) category Co
CO'
Then an
Hom
0,
Co
(A,B)
for
such that the (ordinary,
together with this addition
becomes an (ordinary, ungraded) additive category, and such that (3)
Condition (*) above holds.
Notice also that, in the course of proving Proposition 2, we have verified that when we have data (1) and (2) of Definition
153
Graded Categories
2' above, then the verity or falsity of condition (*) above, ~
which
A (lld)A,d for A where lld is an
priori depends on the choice of a family
all objects
e
in
A
and all degrees d
isomorphism of degree of degree
d
with range
with range
A"),
dE D, A
(the "shift isomorphism
is actually independent of the
choice of such a family.
e
Let group
D.
be a graded category with degrees in the abelian
Then if we regard
e
as a category as in Definition
I, it is not difficult to see that, unless
D
is the zero group,
then virtually never will direct products of two objects in the
e
category
exist.
e
Also, if
is an additive graded cate-
gory graded by the abelian group
e
group, then if we regard
e
then
D,
and if
one of degree
d
A
into
for each
B
dE 0)
nel (or cokernel) of a map in
e"
(since there is no
for each
A
and
B,
but
so that the concept of "kerdoesn't even make sense, if
e
we use just the category structure of ignoring the grading.
is not the zero
as a category as in Definition 1,
is not even a pointed category,
unique "zero map" from
D
as in Definition 1,
It is better to think in terms of Defi-
nition 1', and to pose some "graded" definitions. Definition 3.
Let
D
be an additive abelian group and let
be a graded category with degrees in (1)
Let
I
be a set and let
family of objects in is, an obj ect
A
in
e. e,
ree zero, such that, if ree in ree
d,
D,
and
D.
Then:
(Ai)iEI
be an indexed
Then a direct product of the together with maps B
f i: B -> Ai
is any object in are maps in
then there exists a unique map
e
e
1T i:
A -> Ai
e,
d
(Ai)iEI of deg-
is any deg-
all of the same deg-
f: B ->- A
(necessarily
Section 3
154
of degree
d)
such that
direct product of
TIi
(Ai)iEI
0
f = fi'
all
i E I.
Clearly, if a
exists, then the usual argument
shows that it is unique up to canonical isomorphisms. (2) D,
If
and if
is an additive graded category with degrees in
f: A -->- B
a kernel of and where
C
f
is a map in
is a pair
l:K .... A
C
(K,l)
of arbitrary degree, then
where
is a map such that
K f
whenever
j: L .... A
f
then there exists a unique map
0
j = 0,
0
is an object in
1 =
0
C,
and such that,
is any map (of any degree) such that
Clearly, if a kernel
(K,l)
of
f
h: L .... K
such that
exists, then the usual
argument shows that it is unique up to canonical isomorphisms. Also, i f a kernel of f
f
(K, l)
of
(K, l)
is any kernel of
where
d
=
exists, then there exists a kernel
such that
deg (l) ,
is of degree zero f
deg(l) t- 0,
and
is such a kernel of
f.
-
in fact, if
then
K (K_d,l on_d)'
Therefore, since i t
is no restriction on generality of existence, we henceforth require, for convenience, that
~.his
the definition of a "kernel
(K,l)
additional condition hold in of a map
f
of arbitrary
degree" - namely, we insist henceforth, as we may, that deg (l) = O. (3)
If
C
is a graded (respectively:
category with degrees in
D,
then there exists a unique struc-
ture of D-graded (respectively: the dual category in
C,
CO
of
additive D-graded) category on such that for every map
we have that the degree of
map in the dual categroy f: A .... B
C,
CO
additive graded)
f: B .... A
f: A .... B
considered as a
is the same as the degree of
considered as a map in the D-graded category
C
(and
Graded Categories
155
in the additive case, such that, in addition, if f +g
then the sum
of
f
and
sum considered as a map in
g
C.)
in
f, g E Hom
d
C
(A,B) ,
coincides with their
CO
Therefore, from (1) and (2),
taken in the dual category, we know how to define direct sums of objects in a D-graded category, or cokernel of a map in an additive D-graded category, when these exist. Proposition 3.
(1)
Let
{Ai)iEI
jects in the graded category abelian group
with degrees in the additive
Then
D.
graded category
C
be an indexed family of ob-
Ell A. (resp.: IT A.) exists in the iEI l iEI l in the sense of Definition 3 iff the direct
C
sum (resp.: product) of
Co
graded) category
{Ai)iEI
exists in the (ordinary, un-
of maps of degree
0,
in which case they
coincide. (2)
Let
f: A-+ B
D-graded category
C.
be a map of degree Then
Ker f
the additive graded category Ker (T]~d
iff
0
f)
(resp.:
C
(resp.:
in the additive Coker f)
exists in
in the sense of Definition 3
Coker (f
T]~d))
0
Co
nary, ungraded) additive category 0,
d
exists in the (ordi-
C of degree
of maps of
in which case they coincide.
IT A. exists in CO' with projeciEI l i E 1. Then i f f. : B+A. are maps of the same degtions 'IT i' l l B then fi 0 T]_d: B_ d + Ai are maps in CO' ree d, all i E I, E.g. , suppose that
Proof:
whence there exists a unique map 'IT
i
0
with
f = fi
B
0
T]-d'
(T]~d)-l,
of degree for all
it follows that
i E I.
uct of the
Ai'
in
Co
such that
But then composing this equation on the right
from
d
f: B_ d-+ Ai
B
into
A
Conversely, if i E I,
f
0
(T]~d)-l
is the unique map
such that A, 'ITi'
i E I,
is a direct prod-
in the D-graded category
C
in the sense
Section 3
156
of Definition 3, then considering the universal mapping property d = 0,
in (1) of Definition 3 in the special case that
i E I,
A,TT i'
it follows
obey the universal mapping property condi-
tion for a direct product of the
iE I,
Ai'
in the (ordinary)
CO.
category
The other assertions are proved similarly. Remark:
Perhaps a stronger observation that Proposition 3 is
the fOllowing:
Let
D
V be a category that is a set.
be a D-graded category, and let Let
F
into
be a contravariant, resp.:
CO.
Then
V
covariant, functor from
there exists an object 1i:F(i)->-L,
L
in
C,
CO'
of degree zero for every object f: i ->- j
resp. :
and such that, whenever
resp.: d
C,
and
d
i E 1. Remark:
V
we have
D,
i
F(f) B
in
V,
OTT.=1T., J 1
is any ob13i:B ->- F (il,
and
13i:F (i) ..,. B, are any set of maps all of the same degree
0 F (f) = B. , J 1 sarily also of degree
13:L"" B,
in
is any fixed degree in
such that for every map
resp. :
iff
together with maps TTi:L->-F(i),
such that for every map
ject in
V
has an (ordinary, ungraded) inverse, resp.:
direct, limit in the (ordinary, ungraded) category
resp.:
C
be an additive abelian group, let
B.
such that
TTi
f: i ..,. j
in
we have
V
then there exists a unique map (necesd) in the category 0
13 = 13 , i
resp.:
13
C, 0
13:B..,.L,
1i = 13 , i
resp.:
for all
(The proof is the same as that of Proposition 3). The substance of Proposition 3 is to tell us that uni-
versal mapping property constructions in a D-graded category
C,
that depend on the D-graded structure in the sense of Definition 3 or the Remark following Proposition 3, are closely related to the corresponding usual (ordinary, ungraded) category-theoretic
Graded Categories
157
constructions in the (ordinary, ungraded) category of degree zero in
C.
Co
of maps
Notice however, that such constructions
are very different from the corresponding (ordinary, ungraded) category-theoretic constructions on the underlying category of
C,
ignoring degrees.
These latter category-theoretic construc-
tions rarely exist if D 1 {O}, and are not of much interest. There-
Co'
fore,
C,
not the underlying category of
is the (ordinary,
ungraded) category most closely connected with D-graded univer-
C.
sal mapping property constructions in the D-graded category If
D
tive graded category with degrees in in
C,
then we define
Coim(n~d the f,
1m f) 0
f)
D,
and if
Coim f = Coker Ker f,
f
is a map
1m f = Ker Coker f, Coim f
C
exists in the additive D-graded category (resp.:
Im(f
0
n~d»
A=domain f,
d=deg f.
If both
(If
f.
d = deg f,
then it is easy to see that D-gra d e d category
C
f,
l'ff
CO'
Coim f
then there is induced a natural map from of the same degree as that of
where
and
Coim f
B = range,
1m f into
exist, 1m f
which we call the factorizaB = range f, and
Coim f
(nBd)-l of
and
1m f
A = domain f,
exist in the
has a Coim and 1m in the
usual sense in the (ordinary, ungraded) additive category has a
Coim
and
1m
CO.
three equivalent conditions hold for a map and
a"
And, when these f
in
C,
are the respective factorization maps of A
f on_
d
Co
in the usual sense in the
(ordinary, ungraded) additive category
a,a'
iff
exists in the usual sense in
(ordinary, ungraded) additive category
tion map of
is an addi-
Then by Proposition 3,
whenever these are defined. (resp.:
C
is an additive abelian group and if
if f,
of
in, respectively, the D-graded additive
Section 3
158
C,
category
and the (ordinary, ungraded) additive category
e
exist unique isomorphisms d = deg (f) a = a"
0
Co
the (ordinary, ungraded) additive category
and
p
in the graded category
CO'
then there
of the same degree C,
such that
a =
e
0
a
I,
p.)
Proposition 4.
Let
D
be an additive abelian group and let
be a non-empty additive D-graded category.
Let
Co
C
be the
(ordinary) additive category of maps of degree zero in the graded category
C.
Then the following two conditions,
(1) and
(2) below, are equivalent: (1)
(a)
If
A
and
exists a direct sum of (b)
and degree in B
into
A
A
and
and B
f:A ... B
and i f
f (cl
B
C,
then there
in the sense of Definition 3.
are objects in
C,
is a map of degree
C,
if
d
d
is a
from
A
then the kernel and co-
exist in the sense of Definition 3. The hypotheses as in (b) , i f
is the factorization map of
f,
d = deg (f»
(necessarily of degree (2)
are objects in
in the graded category
kernel of and
D
If
B
then
Ct
a: Coim f "'Im f
is an isomorphism
.
The (ordinary, ungraded) additive category
Co
is an
abelian category. Proof:
Follows immediately from Proposition 3, and from the
observations about factorization maps immediately preceding this Proposition. Definition 4.
Let
D
be an additive abelian group.
Then an
abelian graded category (or a graded abelian category) graded by the abelian group gory
C
D
is a non-empty additive graded cate-
graded by the abelian group
D
such that either of the
Graded Categories
159
two equivalent conditions of Proposition 4 hold. We sometimes use the phrases abelian D-graded category, or D-graded abelian category, for "abelian category graded by D". Remark 1.
Notice, therefore, that if
group, and if
A
D
is a non-zero abelian
is a D-graded abelian category, then the un-
derlying category of
A
in the sense of Definition 1 is not an
abelian category - since in fact
A
is not even pointed.
How-
ever, of course, the category
AD
(of all objects of
A
and
of all maps of degree zero in
A)
is an (ordinary, ungraded)
abelian category. One way of interpreting some of the above material is that Definition l' is perhaps superior to Definition li since e.g. Definition I introduces "the underlying category of the D-graded category
C",
which indeed is a "white elephant":
The in-
teresting (ordinary, ungraded) category associated to aD-graded category
C is
minology:
If
CO. D
We therefore introduce the following ter-
C
is an additive abelian group, and if
is
a D-graded category, then we call the underlying category of
C
in the sense of Definition 1, the white elephant category of
C.
Thus, if
D
is an additive abelian group and
category graded by
D,
C,
of
is a graded
then there are associated two natural
(ordinary, ungraded) categories to gQ£y
C
and the category
all mapsof degree zero of
C.
Co
C:
the white elephant cate-
of all objects of
C
and
It is clear from the terminology
which is the more important one. Remark 2.
By the Remark following Proposition 2, it follows
that:
D
If
is an additive abelian group and if
C is a
Section 3
160
graded category graded by the abelian group
C
D,
then to make
into an abelian graded category graded by the group
is equivalent to:
D
it
Make the (ordinary, ungraded) category
Co
C
of maps of degree zero of
into an (ordinary, ungraded) a-
belian category (in the usual sense), in such a way that condition (*) of Proposition 2 holds.
Since the addition
on an a-
belian category is determined by the category structure, from this last observation it therefore follows that:
D,
d
e
(for all
Home (A, B) Is
e
bel ian group and if
dED)
such
If
D
is any additive a-
A
in
c,
D,
the direct product
exists in the sense of Definition 3, then there exists at
e
most one way of making Example 7. (1)
into an additive D-graded category.
In Examples 1-6 given earlier, In Example 1, if
the D-graded category
AD
is any category, then
A
is an additive category, then
is in a natural way additive. AD
is abelian iff (AD)
In Example 1, in all cases, the category ree zero of the D-graded category ponent category" from
all
is any graded category graded by
such that, for every object
A
A,BEe,
becomes an abelian D-graded category.
This observation generalizes:
A x A
is any
then there is at most one way of introducing an addi-
tion in the that
D
C is any graded category graded
additive abelian group and if by
If
D
into
A,
AD,
AD
If
A
is abelian.
o
of maps of deg-
is identical to the "ex-
consisting of all covariant functors
where
D
is regarded as a category, by
taking for objects the elements of
D,
and for maps only the
identity maps. (2)
In Example 2, for every category
A
we have that
Graded Categories the
~-graded
category
ColA)
defined in Example 2 is in a
~-graded
natural wayan additive
161
category.
ColA)
z-graded category iff the additive category Remark:
A
is an abelian
is abelian.
We construct a peculiar specific additive category,
which we call "Coch".
The objects are the integers (positive,
negative, and zero). = HomCoch(n,m)
j
If
n,m E ~
then define
the addi t i ve abelian group {o} ,
if
m=n or m=n+l, otherwise.
Then there exists a unique composition of maps in "Coch" such that "Coch" becomes an additive category, and such that, for each integer
n E ~,
the element
tity map in Coch from Then if
A
n
IE Hom
Coch
(n,n)
is the iden-
into itself.
is any additive category, then the (ordinary,
ungraded) additive category
Co(Al
O
of objects and maps of
degree zero in the singly graded additive category
ColA)
can
be characterized as follows: (Co (A» 0 = A (Coch) , the category of all additive functors from Coch into
A,
and
of all natural transformations of such functors. (3)
In Example 3, for every additive category
have that the bigraded category additive bigraded category.
D(A)
A,
we
is in a natural wayan
The bigraded category
D(A)
is an
abelian bigraded category iff the (ordinary, ungraded) category A
is an (ordinary, ungraded) abelian category.
Remark.
It is an easy exercise, which we leave for the reader,
to construct an additive category, "Doub", the objects of which are the elements of
~ x~,
such that, for every additive cate-
Section 3
162
gory
A,
if we consider the (ordinary, ungraded) additive cate-
gory
D(A}O
of objects and maps of bidegree zero of the addi-
tive bigraded category
D(A),
then
D (A) 0= A (Doub) as (ordinary, ungraded) additive categories, where
A (Daub)
is the additive category having for objects all additive functors from Doub into
A
and for maps all natural transformations
of such functors. (4)
In Example 4, for every additive category
every integer
n
complexes in category. ger
n
~
A,
Mn(A)
~
0,
the n-graded category
Mn (Al
A
and
of all n-ary
is in a natural wayan additive n-graded is abelian iff
A
is abelian.
For each inte-
it is not difficult to construct an additive cate-
0,
gory
the objects of which are the elements of
such that, for every additive category
A,
(ordinary, ungraded) additive category
(Mn(A»O
all objects in
Mn(A)
71
,
we have that the consisting of
(i.e., of all n-ary complexes in
of all maps of multidegree
n
Al
and
(0, ... ,0), is such that
(M (A» = A (Multn ) nO' where
A (Multnl
Mult
into
n
E.g.,
Multo
such that Mult
2
A
=
=
denotes the category of additive functors from and all natural transformations of such functora
(the additive category having one object
HomMulto (0,0) =71
as ring),
Mul tl = Coch
0,
and
and
Doub.
Exact Imbedding Theorem for Abelian Graded Categories. One can define the notion of functor of graded categories:
Graded Categories Let
D
be a fixed additive abelian group and let
D-graded categories.
0
into
163 C
0
and
A functor of D-graded categories from
be C
is:
(1)
A function
F
0,
the class of objects of
d
HomO (F (A) , F (B) )
C
into
together with d
A function
(2)
from the class of objects of
F(=FA,B)
d
for each degree
into
HomC(A,B)
from dE D,
A,B
C,
objects in
such that (3)
F (idA) = id F (A)'
(4 )
Whenever
all objects
A
in
C,
and such
that
A,B,C F(g
0
d
f E Hom (A, B) C
are objects in f) =F(g)
tor of
0
F(f)
C in
and
and
d,d'
g E Hom
are degrees in
d+d' Homv (A,C) .
D-graded categories and if
d' (B,C), C
CO,V
If
O
FO
of
F
to
Co
C
and
then
is a func-
are the (ordinary, C
Co
V,
and of
is an (ordinary)
tor of (ordinary, ungraded) categories from If
D,
F :C-vv> V
ungraded) categories of maps of degree zero of then the restriction
where
into
func-
Vo'
V are additive D-graded categories and if
F: C + V is a functor of D-graded categories, then the functor d f,g,= Hom (A,B), C
is additive iff whenever jects in
C
and
d
F(f+g) =F(f) +F(g)
is a degree in in
d
Hom (A,B). V
D-graded categories and if
F:C~>V
where
A,B
are ob-
D,
then we have that
If
C
and
V
F
are additive
is a functor of D-graded
categories, then it is easily seen that
F
is additive con-
sidered as functor of additive D-graded categories iff the (ordinary) functor
FO:CO~VO
of (ordinary, ungraded) additive
categories is additive in the usual sense. If
C
and
0
are D-graded abelian categories, and if
164
Section 3
F:C~>V
is an additive functor of additive D-graded categories,
then
is left exact; resp.:
iff
F F
preserves kernels; resp.:
nels and cokernels; resp.: O-+A' F (A")
!
right exact; exact; half exact
A <J A"-+O
cokernels; resp.:
has the property that, whenever
is exact in C,
V.
is exact in
both ker-
then
I f F : C~> V
is a functor of D-graded
FO:CO~>VO
abelian categories, and if
F{A,).l:..i!4F(A)...!:.J.s4
is the induced ordinary
functor on the categories of maps of degree zero, then it is easy to see that
F
is additive; left exact; right exact; ex-
act; or half exact iff the (ordinary) functor of (ordinary, ungraded) abelian categories,
FO:CO~>Vo'
has the corresponding
property. A functor
F:C~>V
of D-graded categories is an imbedding
iff it is injective on the objects, and for every in
C and every degree d
HomV(A,B)
is injective.
d,
the function:
d
objects
d
FA,B:HomC(A,B)-+
Since a functor of D-graded categories
preserves isomorphisms, it is easy to see that, if a functor of D-graded categories, then FO:CO~~>VO
A,B
F
F:C~~
V is
is an imbedding iff
is an imbedding of (ordinary, ungraded) categories. F: C~> V
In particular , it follows that, if D-graded abelian categories, then
F
is a functor of
is an exact imbedding of
D-graded abelian categories iff the induced functor of ordinary, ungraded abelian categories on the categories of maps of degree zero,
FO:CO~>VO
is an exact imbedding in the usual sense
([lAC.]) of abelian categories.
If
F:C'VU> V
is an exact imbed-
ding of D-graded abelian categories, then all the familiar properties of exact imbeddings of (ordinary, ungraded) abelian categories hold, see [I.A.C., Introduction], including about exact se-
165
Graded Categories quences, inverse-composites, subobjects, etc. If
A
is a D-graded abelian category, then let
AO
be the
(ordinary, ungraded) abelian category of maps of degree zero of A.
Then we have constructed, in Example 1 above, the category
(Ao)D
of D-graded objects in the abelian category
AO'
which
is also a D-graded abelian category. Theorem 5.
There exists a canonical exact imbedding of D-graded
abelian categories from
A
into
Proof:
A
in
For each obj ect
ject in and
If
are objects in
A,B
n~)dED '
A let F (A)
e f E Hom (A,B), where A
A,
verify that
F
Corollary 5.1. Categories.)
(Ao)D.
e
an ob-
0
is a degree in
e
then define
which is a map of degree
in the D-graded category
(Ad)dED'
F(f)=«n
from
B e+
F(A)
d)
-1
into
0
f
0
F(B)
We leave it as an exercise to
is a functor, and is an exact imbedding. (Exact Imbedding Theorem for D-Graded Abelian Let
be an additive abelian group and let
0
be a D-graded abelian category that is
'Cl
set. Then there exists
an exact imbedding of D-graded abelian categories from (the D-graded abelian category),
A
{abelian groups}D,
A
into
the cate-
gory of D-graded abelian groups. Proof:
AO
is a set.
is an (ordinary, ungraded) abelian category that Therefore by the Exact Imbedding Theorem
there exists an exact imbedding groups}.
G
grom
AO
into
([~l),
{abelian
This clearly defines naturally an exact imbedding of
D-graded abelian categories, call it
o
{abelian groups}.
from
into
By Theorem 5 above, we have a canonical
exact imbedding of abelian D-graded categories, The composite functor, the proof.
GO
0
F:A'V'v> {abelian groups}D,
completes Q.E.D.
Section 3
166
Of course, the last
c~rollary,
the Exact Imbedding Theorem
for O-Graded Abelian Categories, reduces many constructions and proofs for arbitrary O-graded abelian categories, to the special ~he
case of
category~
O-graded
{abelian groups}O, of D-graded
abelian groups. Of course, given any O-graded abelian category that is not
A,
a set
if
S
there exists a O-graded subcategory
S
O-graded subcategory (i.e., such that for all objects that
S
A,
is any subset of the objects of
A,B
in
S
of
A,
then
that is a full
d d HornS (A,B) = HomA (A,B)
and all degrees
d
0),
in
such
is an abelian O-graded category, such that the inclu-
sion functor:
[3'V'v>
A
is exact, and such that
Then the last corollary applies to
S.
S
is a set.
In this way, the appli-
cations of the Exact Imbedding Theorem for Abelian O-Graded Categories that are sets, can be used also to prove results even for those that are not sets, just as in the ungraded case. Exercise 1.
V
and
0
Let
be an additive abelian group and let
be D-graded categories.
ural equivalence from Exercise 2. Let
-+
E
into
Then define the term a O-nat-
V.
(Change of Grading Group, Non-Additive Case) . be an additive abelian group and let
0
graded category.
1>: 0
C
Let
E
be an epimorphism of abelian groups.
Ccrude
are objects in
C
e Hom crude(A,B) C E
and i f U
dEO 1> (d)=e
be a 0-
Then one can asCcrude E
are the same as the objects in
E
C
be another abelian group and let
sociate an E-graded category which we denote jects in
C
e E E,
then define
d ({d} x Home (A, B) )
e.
•
The obIf
A,B
Graded Categories
167
Horn e d (A,B) is the disjoint union of the sets: ecru e E for all dE D such that ¢ (d) = e). Then with the
(that is, d
Home(A,B)
ecrude
obvious composition, one verifies that graded category. (1)
If
e
becomes an E-
E
Some special cases: is an additive D-graded category, and if the
epimorphism of additive abelian groups
¢:D+E ecrude
morphism, then the E-graded category
E
is not an isois not additive
(since the disjoint union of more than one group has no natural In fact,
structure as group. even prove that
ecrude
in these circumstances, one can
is not even an E-graded pointed cate-
E
gory) . If
(2) E=;Z
and
(n,m) E;Z
D=;Z x;Z,
¢:D+E
X;Z,
the additive group of pairs of integers,
is the sum map,
¢(n,m) =n+m,
all
then a "D-graded category" is a bigraded category,
and an "E-graded category" is a singly graded category.
There-
fore every bigraded category defines a singly graded category, by the "crude" procedure. More generally, if
(3)
p:{l, ... ,n}+{l, ... ,r} epimorphism quiring that f
l
,· .. , f
r
,
p
l
r-graded category,
¢p'
are integers, and if
P
of additive abelian groups, by rewhere
(.)' l
is the canonical
Then, by means of
r
is any onto function, then define an
¢=¢ :;Zn .... ;Zr ¢ (e.) = f
1 <
;Y-basis of
resp. :
n
;Z ,
resp. :
every n-graded category
ecrude ' ;Z r
e
of
;Z
r
.
defines an
by the "crude" construction of Ex-
ercise 2. (4)
In the special case
there is only one function ¢p
r = 1
of special case (3) above,
p:{l, ... ,n}+{l}.
as in special case (3) above.
This
p
defines
Therefore every n-graded
168
Section 3
category defines, by the "crude" procedure, a singly graded category. (5)
If
¢:D+ {oJ
D
is any additive abelian group then let
be the unique homomorphism to the trivial group.
every D-graded category
c{~}de -
C
defines a
Then
{OJ-graded category
that is, an ordinary, ungraded category by the "crude"
construction.
Of course,
Ccrude {O }
"white elephant" category of
C
is simply the underlying in the sense of Definition 1.
Special cases (1) and (5) above show the problems of the "crude" way of passing from a D-graded category to an E-graded category.
E.g., in (5), we have previously observed how dif-
ferent are the categorical properties of
C
and of
Ccrude {O} -
and (1) above shows just "how crude" the construction is. Exercise 3. D
(Change of Grading Group, Additive Case).
be an additive abelian group and let C be an additive D-
graded category. ¢:D+E C ' E
Let
e EE
and
Home (A,B) C E
Then we define
C E
are the same as the objects in
A, B
are objects in Ell
C,
C.
we define
d HomC(A,B).
dED ¢(d)=e
f= (fd')d'ED :A+B and g= (gd")d"ED :B+C are maps ¢(d')=e' ¢(d")=e" C of degrees e' and e" respectively then define E
L" gd"ofd')dED a map of degree e' + e" from d ,d ED (d) , " d'+d"=d ¢ =e +e into C in CEo Then CE ' together with the indicated no-
go f=(, A
be another abelian group and let
an associated additive E-graded category.
Whenever
in
E
be an epimorphism of additive groups.
The objects in
If
Let
Graded Categories
169
tion of "map" and "composition", is an additive E-graded cate(Notice that, if we had taken the direct product of Horn's
gory.
instead of the direct sum of Horn's in defining "maps" in
CE ,
that we would not have been able to define composition of maps). (1)
If the additive D-graded category
C
is an abelian
D-graded category, then in general, the additive E-graded category
CE
is not an abelian E-graded category.
CE
by Proposition 4,
(Notice that,
is abelian iff the (ordinary, ungraded)
category: (2) and let let K
Let
A
C = AD,
¢: D -+ E
be an (ordinary, ungraded) additive category the category of D-graded objects in
A,
and
be an epimorphism of addi ti ve abelian groups.
be the cardinality of
nary) category
A
Ker ¢,
Let
and suppose that the (ordi-
is closed under direct sums of
< K objects.
Then the assignment:
defines an additive functor (AD)
E
into
AE.
The functor
I
of I
E-graded categories from of E-graded categories is
easily seen to be an imbedding(*) of E-graded categories.
Every
(*) Actually, technically speaking, the functor I of Egraded categories as constructed above is only a faithful functor (that is, a functor that is injective on the Horn's but not necessarily on the objects) rather than an imbedding. However, faithful functors of E-graded categories share all of the important nice properties of imbeddings. (In fact, if F: ~ is a faithful functor of E-graded categories, and if C has "enough objects in each isomorphism class", then F is isomorphic to an imbedding. Therefore, in (2) if we replace A by a D-equivalent category, having enough objects in every isomorphism class, then the functor I constructed in special case (2) above can be taken to be an imbedding.)
Section 3
170
object of of
(AD)
E
(3)
AE
is isomorphic in
under
AE
to the image of some object
1.
In special case (2) above, if the kernel of
¢:D
->-
E
is finite, then the additive imbedding - more precisely, additive faithful functor -
I
of special case (2) is a full im-
bedding - more precisely, full faithful functor - and such that every object of the range category of object in the image of
I.
I
is isomorphic to an
Therefore, in this case,
I
is an
equivalence of E-graded categories, and therefore abelian E-graded category iff
AE
is an abelian E-graded cate-
gory; and of course, this latter occurs iff
A
is an abelian
category. (4) where
If
D
A
is an arbitrary additive D-graded category,
is an addi ti ve abelian group, then let
the unique homomorphism to the trivial group. A{O}'
¢p:~
Let
nand
p: {I, ... ,n}
n
be
Then we have
an additive (ordinary, ungraded) category. (5)
let
¢: D -+ {O}
-+~
r
means of
-+
r
be integers such that
{I, ... ,r}
be an onto function.
constructed in (3) of Exercise 2. ¢p'
1 < r < nand
Therefore, by
every n-graded additive category
r-graded additive category.
C
sider the additive n-graded category
A,
then
we have ~
category.
If
A
C = A~ r'
A
Then if we con-
n
of all n-graded
an additive r-graded
is abelian, then as we have seen in Example
A~
7, part (1), the n-graded additive category abelian category.
defines an
As a further special case, let
be any (ordinary, ungraded) additive category.
objects in
Then we have
However, if
r
n
is an n-graded
then it is easy to see
that the additive r-graded category ~
r
is not, in general,
Graded Categories abelian; A
a counterexample is
171
A = category of abelian groups.
If
is an additive category such that denumerable direct sums of
objects exist, then we have the functor
I
of special case (2),
a canonical additive imbedding - or, more precisely, a canonical additive faithful functor - from the r-graded additive category
n (A~)
into the r-graded additive category
~r
graded objects in (6) Then
A~
r of all r-
A.
A special case of (5) is the one in which
p
is necessarily "constant function one".
for every additive n-graded category singly graded category
C~.
C
r = {lJ,
Therefore,
we have an associated
As a further special case, for
every (ordinary, ungraded) additive category
A,
such that de-
numerable direct sums exist, we have an additive imbedding - or, more precisely, an additive faithful functor - I of additive n (A~ ) singly graded categories from into A~ . The image, ~
of an n-graded object
I (A),
A
in
A
the associated singly graded object (7)
Let
and let
A
n,r,p
and
¢p
of
is called
A.
be as in special case (5) above
A.
Then we have
the category of n-ary, resp.:
abelian category category.
I,
be an additive category such that denumerable
rect sums of objects exist in Mr(A),
under
A,
Mn(A),
diresp.:
r-ary, complexes in the
an n-graded, resp.:
r-graded, abelian
Then, by setting up appropriate sign conventions for
coboundaries, it is not difficult, as in special case (5) above, to define an additive functor
that is an additive imbedding - more precisely, an additive faithful functor- of r-graded additive categories.
If
A
is
172
Section 3
an n-ary complex in the abelian category
A,
then
I(A)
is
called the r-ary complex obtained from the n-ary complex by contracting indices according to (8)
A
p.
A special case of (7) above is the one in which
Then necessarily Mr (A) = Co (A) .
r = 1.
is the constant function one, and
p
In this case, for every n-ary complex
the cochain complex
A E Mn (A) ,
thus obtained is called the
I (A) E Co (A)
associated singly graded complex of
A.
Special cases (6) and (8) of this Exercise, and also special case (4) of Exercise 2 above, motivate the following terminology:
If
f
n-graded category
le t
D
C,
then by the total degree of
Let and
A E
be addi ti ve abel ian groups and let
full subcategory d
many
object in
C
of
AD
such that A.
C
¢ : D ->- E
Then one can consider the
¢ (d) = e
e E E,
there exist only finitely
and such that
Ad
is not a zero
is an abelian, D-graded subcategory of
and the inclusion:
C~>AD
be
generated by those objects
such that, for every
dED
we mean
be an (ordinary, ungraded) abelian category,
an epimorphism of additive groups.
(A )dED
f
in an
d = d l + •.• + d . n
the integer (9)
(dl, ... ,d ) n
is a map of multidegree
is exact.
generality, we can construct a functor cial case (2) above on objects of
C,
AD,
Then, at this level of "I" and
exactly as in speI
is a full imbed-
ding - or, more precisely, a full faithful functor - of E-graded categories from
C E
into
AE;
moreover every object of
isomorphic to an object in the image of graded additive categories I
I.
AE
Therefore the E-
C and AE are E-equivalent with E being one half of the E-equivalence; and therefore C is E
is
Graded Categories
173
an abelian E-graded category. Let
(10)
A
be an abelian category and let
n
be a non-
negative integer. Then we have the n-graded abelian categories n A71 Then, of course, we have the "stripping funcand M (A). n n tor" from
into
Mn(A)
A71,
which to each n-ary complex asso-
ciates the corresponding n-graded object in
A.
This "stripping
functor" is an exact imbedding of n-graded abelian categories (but of course is not a full imbedding unless
A
is equivalent
to the zero abelian category).
there exists an integer Pl' ... 'Pn gory
B
n
~ -N.
Fn(A)
and
Bn(A)
n=O
unless
are both n-graded abelian categories.
Fn (A)
(resp.:
of
objects (resp.: n-ary complexes) in . A
Bn (A) )
the n-graded
that are bounded be-
The stripping functor is an exact imbedding of n-graded
abelian categories from
Bn(A)
For every positive integer
tion
such that
under the "stripping functor" is in
We call the obj ects of
low.
gen-
generated by all n-ary complexes such
that the image in Fn(A).
,p
n
Similarly, we have the full n-graded subcate-
of
(A)
Pl"" A
such that
N
A71
of
We have the full n-graded subcategory Fn(A) Pl" .. ,p (A n) n era ted by all objects (Pl"" ,Pn)E71
p : { 1, ... , n} ... {l, ... , r} ,
into
Fn(A).
r
and every onto func-
p
structed as in special case (5) above. tained in the full subcategory
C
of
: (;r
n ,+) ...
Then n
A71
(il
r ,+)
Fn(A)
be con-
is con-
constructed in
special case (9) above, and is a full subcategory of
C.
There-
fore, from special case (9), we see that the restriction of the functor
I
of special case (9) is
r-graded abelian categories:
h~lf
of an equivalence of
Section 3
174 F
n
(A)
'J'
r
'VV>F (A). r
The image of an n-graded object
bounded below under this
functor
I
in
from
~
contracting indices following the function
A
F
A
Similarly,
is called the r-graded object obtained
(A)
r
n,r
and
p
p.
as above, we obtain, by the con-
struction in special case (9) above, an additive functor of rgraded categories I :B
(A)
n
'VV> B
('J'r ,+)
(A).
r
One can show in this case that the r-graded additive category B (A) n
tor
is an r-graded abelian category, and that the func('J'r,+)
is an exact imbedding - or, more
I: B (A) 'V'u> B (A) n ('J'r ,+) r
precisely, an exact faithful functor - of r-graded abelian categories.
The image of an n-ary complex
category
A
A
in the abelian
that is bounded below under this functor
called the r-ary complex associated to dices following the function
A
~
I
is
contracting in-
p.
(11) A further special case of special case (10) above is the one in which tion one.
Then
r = 1, I
so that necessarily
p = constant func-
for n-graded objects bounded below is
one half of an equivalence of singly graded abelian categories: F
n
(A)
The image
'J'
'V'u>
F 1 (A) •
I(A) of an n-graded object
low in the singly graded abelian category functor
I
A
that is bounded be-
Fl (A)
under this
is called the associated singly graded object of
And, similarly, when
r = 1,
I constructed for n-ary com-
A.
Graded Categories
175
plexes bounded below in special case (10) above is then an exact imbedding - more precisely, an exact faithful functor -of singly graded abelian categories, 1:
The image gory
A
Bn (Al( ;z , + )CV\,> Bl(A).
I(Al
of an n-ary complex
A
in the abelian cate-
that is bounded below under this functor
I
is called
the associated singly graded complex, or the associated cochain complex, of
A.
It is an object in
dexed cochain complex in
¢:O
+
E
that is bounded below.
(Change of Grading Group, other direction).
Exercise 4. Let
A,
and
0
E
be additive abelian groups and let
be a homomorphism of additive groups.
E-graded category
A,
the same as the objects of every pair of objects A
of degree
into ¢ (d)
A.
A,B,
DA.
The objects of
F.or every degree
DA
dE D,
in the E-graded category
oA A.
are
and
we define the maps of degree
in the O-graded category
B
Then to every
we associate a O-graded category, as in
Definition 1', which we denote by
from
CoCA) =Ml(A), Le., a ;z-in-
d
to be the maps That is,
d ¢(d) Hom A (A,B) = Hom (A,B). A o
The composition in
OA
is defined in the obvious way.
one verifies easily that "maps of degree
d"
oA,
together with this notion of
and composition, is a O-graded category.
It is immediate that, if the E-graded category ditive, respectively: gory
DA.
Then,
A
is ad-
abelian, then so is the O-graded cate-
Similarly, if the D-graded category
A
is closed
under, e.g., denumerable direct sums (in the sense of Definition 3); or under arbitrary direct products (in the sense of
Section 3
176
Definition 3); or under any analogous universal mapping property construction; then the D-graded category responding property.
DA
inherits the cor-
The reason for the assertions of this
paragraph being true, is that the E-graded category D-graded category
DA
A
and the
have the same category of maps of degree
zero:
and, as we have seen above, all the properties listed in this paragraph depend only on the category of maps of degree zero. Therefore, the construction in this Exercise, of "changing the grading group in the other direction", is indeed a smoother operation than those discussed in Exercises 2 or 3. Remark:
The reader should note that the construction of Exer-
cise 4 above is in general not an inverse (in fact, not in general either a left inverse or a right inverse)
of either the
construction of Exercise 2 or that of Exercise 3. ?ropos±tion 6. A
Let
D
be an additive abelian group and let
be a D-graded abelian category.
Suppose that the D-graded category products of system
i
2card (I)
(A,a
ij
).
'cI
~,J"
objects (*).
Let A
I
be a directed
set~~.
is closed under direct Then, given any inverse
of objects and maps in the underlying
white elephant category of
A
(as defined in Definition 1),
(~)It is equivalent to say, suppose that the (ordinary, ungraded) category A of all objects, and of all maps of degree zero, of A, is cl sed under direct products of < card (I) ob-
g
jects.
177
Graded Categories
ij lim (Ai,a ) in the (ordinary, ungraded) iEI white elephant category of A exists. the inverse limit
Proof:
Recall that, for every
definition
dE D,
A Ad "".... A nd:
d.
of degree
finite, the Proposition is trivial. is infinite.
Then let
~
i
i O}.
iO
be an element of
Then since
by
I
I,
), all
is
I
I,
I
and let I,
exists, then this
call it
i E I,
Then for each iO
and
i ij (A,a ). ·cI. l.,)"
Therefore,
if necessary, we can assume that there
J
exists an element in
d =- deg (a i
Ad
is a corinal subset of
J
latter is also an inverse limit of replacing
If the set
by
Therefore assume that
it is easy to see that, if
i E 1.
A E A,
of "D-graded category", we have an object
an isomorphism
J = {i E I:
and every
i E I.
such that
0,
we have the map
0
~
i,
all
aiO: Ai..,. AO.
Let
Define
i P = IT (A ) d ' the dir. product in the sense of Def. 3. iEI i
Then we have ree zero.
7T
i
:p .... (Ai}d.'.
the i'th projection, a map of degl.A l. i I':l i nd.:(A }d.""A, an isomorphism of l. l.
We also have
Ai .... A. is a map of Pi = n d . 0 7T i. Then p.:P l. l. iO l. = -deg (a ) . Whenever j~i are elements of I,
degree
di ·
degree
d
i
Let
have that ·0
a l.
..
0
·0
a) l. = a ) ,
·0
whence
..
·0
deg(al. } +deg(a)l.} =deg(a)}. deg(a
jO
} =-d .. )
Hence, whenever
Therefore
j > i
in
I,
But
deg(a
ji
deg(a
iO
) =-d , i
} =d. -d .. l. J
we have that
we
Section 3
178
(1)
j::.-.i
in
I
Therefore, since
implies
deg (a j i
a ji
and
p
are both maps from
A,
gory Let
K"
~J
Then
0
into
we can form =Ker(a
ji
0
pj
AO
category
A,
zero of
i
Ai ,
pj _pi),
P.
p j ) = deg (p i ). have the same degree,
all
whenever i,j E I
j:,i.
i,jEI,
j > i.
such that
is an indexed family of
Since the (ordinary, ungraded) abelian
is by hypothesis closed under direct products of
.s. card (I),
the proof of Corollary 2.1 of section
1 applied to the (ordinary, ungraded) abelian category
AO
is closed under forming infima of
objects of an object. of the subobjects: P,
exists.
A ' O
2. card (I)
In particular, the infimum, call it
Koo, ~J
all
(i,j)E{(i,j)ElxI: j::...i},
It is easy to see that
limit of the inverse system Remark 1.
consisting of all objects and all maps of degree
collections of
srows that
and
in the additive D-graded cate-
ajiopj_pi,
(Kij){(i,j)EIXI: j::...i}
(I) subobjects of
p
0
D
subD, of
is the desired inverse
i ij (A,a ),
Q.E.D.
1,J'EI.
A consequence of the construction of the last propo-
sition, is Corollary 6.1.
Under the hypotheses of Proposition 6, we have
also that the (ordinary, ungraded) abelian category
AO
is
closed under inverse limits of inverse systems of objects and
Ao
maps in
indexed by the directed set
verse system, the inverse limit in
AO
I.
For any such in-
is also an inverse limit
in the (ordinary, ungraded) white elephant category of Remark 2. spect.
A.
Theorem 6 and Corollary 6.1 are unusual in one re-
Namely, it is a case when a universal mapping property
construction (namely, the inverse limit over a directed set) turns out to exist in the "white elephant" category iff it
Graded Categories
179
exists in the category of maps of degree zero.
For most other
common universal mapping properties (e.g., the direct product of objects, kernel of a map, etc.), it usually
turns out that
the "white elephant" category is pathological for the construction. Remark 3.
Of course, Proposition 6, Corollary 6.1 and Remark 2
have corresponding statements about direct limits, which immediately follow by applying these results to the dual D-graded O
abelian category Definition 5.
A
Let
•
D
be an additive abelian group, let
a D-graded abelian category, and let Then by a subobject (resp.: the object
A
A
A.
graded abelian category is a subobject of
of
B,
f-l(T),
f (S),
A
quotient-object; subquotient) of
maps of degree zero of
A,
to be
If
A,
A.
f:A
->-
B
1).
If
A
in the
is any map in the D-
of any degree, and if
0
we mean a
of all objects and
AO
then define the image of 1m (f
T=
then define the inverse image of
{
Sunder
(D, j) } T
S = { (C, i) }
under
Namely, if
d = deg f,
same as the fiber product of the diagram:
f,
is a subobject f,
denoted
to be the fiber product of the diagram:
(This always exists:
be
quotient-object; subquotient) of
(ordinary, ungraded) abelian category
denoted
be an object in
in the D-graded abelian category
subobject (resp.:
A
then it is the
180
Section 3
in the (ordinary, ungraded) abelian category degree zero of
A).
AO
of maps of
Then the Lemma immediately preceding Theo-
rem 3 of section 2 generalizes to D-graded abelian categories. That is, in the statement of that Lemma, replace the phrase "an abelian category
A"
with "a D-graded abelian category
A".
Then the resulting Lemma is also valid. Let
Proof:
d = deg f.
Lemma is true for
(n~)-l
0
f
is an isomorphism, the
Then since
(n~)-l
iff it is true for
f
0
But
f.
is a map of degree zero, and is therefore a map in
the (ordinary, ungraded) abelian category
AO'
(n~) -1
verity of the generalized Lemma for
0
f
Therefore, the follows from
the verity of the Lemma preceding Theorem 3 of section 2 for the (ordinary, ungraded) abelian category
AO
(n~) -1 of: A..,. Bd
AO·
in the abelian category
Recall that, if AEA where
and every Ad
A
dE D,
A
we have fixed a specific pair A
such that
and
in
A,
where
Definition 6. B
"0"
Let
A
and
~
additive relation
A
deg (nd) = d.
AX B . d
AO
is an isomorphism
We can and do in-
= A, n~ = idA'
is the zero element of
all objects
D.
be a D-graded abelian category.
be obj ects in
subobject of
A
nd :Ad ..,. A A
sist that the choice is such that A
Q.E.D.
is a D-graded category, then for every
is an object in
in the category
and the map
R
A, from
and let A
into
d ED B
Let
be a degree.
of degree
(An identical definition is:
d
Then
is a
An additive
Graded Categories relation from
A
into
A,
an category
B
A,
lation from
A
jects in So R,
A
from
B and
of degree
C
d,e E D,
First, let
d,
is an additive re-
R
If
Bd - )
of degree
B
into
into
S
and e,
is an additive
where
A,B,C
are ob-
then we define the composite relation
an additive relation from
as follows:
in the D-graded abeli-
of all objects and maps of deg-
AO'
A
into
relation from
d,
is an additive relation in the (ordinary, un-
graded) abelian category ree zero of
of degree
181
n :C + d e
-+-
A
into
C e
C
of degree
d + e,
be the isomorphism of deg-
n~+e (nC)-l ---" C e " C ) _ Then e e SC: B x C , so that (n~ x n) -1 (S) c: Bd x Cd +e Also Rc: A x B e d B -1 Therefore Rand (n x n) (S) can be thought of as being d (ordinary, ungraded) relations in the (ordinary, ungraded) aree
d,
belian category A,
from
(C d +
the composite:
A
of all objects and maps of degree zero of
AO
into
B , d
C + , respectively_ d e B -1 [(nd x n) (S) loR in the
and from
Bd
Therefore the composite relation:
into
(ordinary, ungraded) abelian category AX Cd +e -
a subobject of
But then
AO
(n
B d
makes sense, and is
x n)
-1
(S) 1 oR
can
equally well be thought of as being an additive relation of degree
d +e
from
posite relation_
A
into
C,
That is,
and we define this to be the comS
B
R = (nd x n)
-1 (S))
0 R, where C -1 C n=(n e ) on d +e - Also, if R is an additive relation from into B of degree d in the D-graded abelian category A, 0
then we define the inverse relation from
B
gory
A_
into
A
Namely,
of degree R
-d
R-1 ,
an isomorphism of degree
an additive relation
in the D-graded abelian cate-
is a subobject of
the "twist" isomorphism:
A
Bd x A~ A x B d -d:
A x Bd _ Also
Let
T denote B -1 A (n ) x n_ is d d Then define R- l
Section 3
182
to be the inverse image under the composite isomorphism To [(1'1
B x A_
d
B -1
d
)
,
A
""
-1
xn_dl:BxA_d-+AxB . Then R is a subobjectof d l i. e., Ris an additive relation from B into A
is a map of degree
d
A,
in
B -1 (1'1 ) d
0
f:A .... B d
R
.
d
from
f:A .... B
If
B,
into
A
f,
~of
then we define the
r f , an additive relation of degree follows.
-1
completing the definition of
of degree -d,
as
is a map of degree zero, and there-
AO'
fore is a map in the (ordinary, ungraded) abelian category
A.
of all objects and maps of degree zero of
r (n~) -1
the graph
0
f
of the map
AO'
ungraded) abelian category from
A
into
B , d
(1'1~) -1
Therefore we have
f
0
in the (ordinary,
AO
an additive relation in
or eql,livalent1y, a subobject of
Ax B . d
But this is also an additive relation in the D-graded abelian
A from
category
A
to be the graph of fined to be
r
f.
(1'1 B )-l
is the graph of
and
f
That is, the
d,
and we define this
rf
~
of
then that map is uniquely determined: and
f .... r f
resp.:
S,
resp.:
resp.:
C,
into
resp.:
e,
resp.:
of degree
if
d +e +f
d, e, f E 0 T, B,
I.e., if
are degrees in
is a relation from resp.:
f, from
then A
go f
g
is de-
Similarly, it is easy to see that
composition of relations is associative. A,
(I.e., i f
preserves composi tes.
r go f=r g or f ·)
objects in
is de-
f
are maps of arbitrary degrees such that
fined, then
f
Of course, if an additive relation 0
R map,
the correspondence:
B of degree
into
C,
resp.:
A, 0,
0
and if resp.:
of degree
(ToS) oR=To (SoR), into
A,B,C,O
are
R,
a, d,
relations
o.
Finally, we pose two more related definitions, that will be useful later.
Namely, let
A
be a O-graded abelian
categor~
183
Graded Categories let
A
and
B
be objects in
quotient of
A
and let
Let
dE D,
and let
B
of degree
d
B
of degree
d).
A,
let
T
into
V
let
f
to
as V
T
U
(resp.:
d. V
deduced from
fJ. T
T
(resp.:
If the additive relation from (resp.:
f)
f) ,
from the map
f)
as
T
(resp. :
U
in-
by passing to the subquo-
the same degree
d
Qy
fJ
Notice that it has the same deg-
U
V
into
We call this latter, the additive
the resulting uniquely determined map:
into
A
an additive relation from
into
deduced from
U
into
be a map from
tients should happen to be the graph of a map, say
from
A
B.
Then we have the additive relation
passing to the sUbquotients. ree
be a subquotient of
be an additive relation from
(respectively:
of degree
relation from
be a sub-
l
V = { (B , Sl)} l
(resp. : U
U = { (Al,R )}
as
-+
then
fg'
necessarily of
V,
is called the map
deduced from the additive relation
T
(or
Qy Eassins to the subguotients.
The proofs of all the assertions following Definition 6 are as follows.
If the D-graded abelian category
A
is a set,
then by Corollary 5.1 there exists an exact imbedding of Dgraded abelian categories from abelian groups.
A
into the category of D-graded
Therefore in this case the assertions reduce
to the case in which the D-graded abelian category
A
is the
category of D-graded abelian groups, where the assertions are trivial by set-theoretic methods. If
A
is not a set, then let
S
be a set of objects con-
taining all the objects under consideration. an exact, full D-graded abelian subcategory taining all the objects in
S,
such that
Then there exists A'
A'
of
A
is a set.
conThen
184
Section 3
to prove each given assertion for for
A',
A,
it suffices to prove it
which has been done in the last paragraph.
Section 4 Spectral Sequences in a Graded Abelian Category
Definition 1.
Let
D
be an additive abelian group, and let
be a D-graded abelian category.
Then by a spectral seguence in
the D-graded abelian category
A
gether with an indexed family
(Er,dr,Tr)r>O'
object in from
A,
Er
all integers
r
~
we mean, an integer
0,
and
dr:E r
r
where -+
Er
' O
Er
tois an
is a map
into itself (of any possible degree; we do not even in-
sist that the dr's have the same degree for different such that T : r
A
d
r
0
d
r
= 0,
all integers
[Ker(d )/Im(d )] ~E +1 r r r
If
D
~
A,
all
rO) ,
and where
is an isomorphism of degree
the D-graded abelian category Example 1.
r,
r
r
~
0
in
r O.
is the zero-group, then of course the notion
of "spectral sequence il a D-graded abelian category" reduces to that of "(ordinary, ungraded) spectral sequence in an (ordinary, ungraded) abelian category", as defined in section 1. Example 2.
If
D
is any additive group, and if we consider
the D-graded abelian category
AD,
ungraded) abelian category, then
AD
objects in the abelian category
3.
A
where
A,
A
is any (ordinary,
is the category of D-graded discussed in section
spectral sequence in the D-graded category
AD
will
be called a D-graded spectral sequence in the jordinary, ungraded) abelian category
A.
Thus, explicitly, if
additive abelian group, and if
A
185
D
is any
is any (ordinary, ungraded)
Section 4
186
abelian category, then a D-graded spectral sequence in the abelian category
A
is, an integer
r
' O
together with an in-
dexed family:
where (1)
En r
and where
is an object in
d:: E:
+
E:
A,
all
nED,
is a map in the D-graded category
AD.
That is, (2)
for each integer
r
~
r 0'
we have a degree
a
r
ED,
such that (3 )
d
n r
is a map in the abelian category all degrees nED,
to
A
from
En
in-
r
all integers
In addition, we must have that (4)
all
nED,
all
r~rO.
And finally, (5)
Tn r
is an isomorphism in the abelian category
(1)-(5) above give
A,
an equivalent definition of aD-graded spec-
tral sequence in the (ordinary, ungraded) abelian category
A.
Three special cases of Example 2 are worthy of special mention. Example 3.
The special case of Example 2 in which
the additive group of integers.
Then if
A
D = (;Z, +) ,
is any (ordinary,
ungraded) abelian category, a ;z-graded spectral sequence in (i.e., a spectral sequence in the
;z-graded abelian category
A
Graded Abelian Category A7)
187
is called a singly graded spectral sequence in the (ordi-
nary, ungraded) abelian category
A.
Thus, explicitly, if
A
is an (ordinary, ungraded) abelian category, then a singly graded spectral sequence in
A
is:
an integer
(E~,d~,T~)nE7
with an indexed family
r
where
' O
together En
(1)
is an
r
r~rO
object in r
~rO'
A,
all
nt:7,
we have an integer and every integer
Cl n,
~
r 0i
t:7,
and for every integer
all integers
and where
(4)
r
n,r
A:
integers
r
such that
[Ker(dn)/Im(dn-Clr)]':';.En+I' r r r
Cl ( = deg d;) r
In most practical examples of singly graded
spectral sequences, however, we normally have that r> r - 0
integers
all
~rO'
In this abstract definition, the integers can be arbitrary.
such that
is an isomorphism in the (ordinary, un-
graded) abelian category n,r
for each integer
(2)
we have a map
such that (3) r
r~rOi
all
(Le., all the
d*'s r
Cl.r=+l,
have degree +1).
all
A singly
graded spectral sequence with this property will be called conventional. Remark:
be a singly graded spectral se-
Let r~ro
quence in an abelian category integer
a
Eo
7
such that
Cl
r
A.
Suppose that we have a fixed
= deg d; = Cl.,
all integers
r
~
rD.
Then: dn n) ( En r' r,T r r>r - 0 is an (ordinary, ungraded) spectral sequence in the abelian
Case 1.
category
If
A.
sequences in
Cl. = 0,
then for each integer
n,
In this way the study of singly graded spectral A
such that all the
Cl.r'S
are
0,
reduces to
that of studying denumerably many (ordinary, ungraded) spectral
188
Section 4
A.
sequences in Case 2.
a f 0,
If
then for each integer
i,
0 ~ i ~ I a : - I,
define
all integers
o~ i
~
Ia I -
r
I,
~
r
o·
Then, for each of the
all
n E ;z ,
Ia I
integers
i,
we have a conventional singly graded spectral se-
quence: ( iEnr' idnr' iTn) r nE;z r~rO
In this way, we see that to give a singly graded spectral sequence in the abelian category the same non-zero integer
a,
A
such that all the ar's
are
is exactly equivalent to giving
lalconventional singly graded spectral sequences in the abelian category
A.
Combining Case 1 and Case 2, we see that, the notion of "singly graded spectral sequence in the abelian category ar's
~
all equal for different
r,"
A, really
reduces to those of "(ordinary, ungraded) spectral sequences in A"
and "conventional singly graded spectral sequences in
Example 4. group
0
The special case of Example 2 in which the additive is the group
(~x~,+).
Then a
tral sequence in an abelian category
A
spectral seguence in the abelian category if
A
A".
(~x~)-graded
spec-
is called a bigraded A.
Thus, explicitly,
is an (ordinary, ungraded) abelian category, then a bi-
graded spectral sequence in the abelian category with the integer
rO
is, an indexed family:
A
starting
189
Graded Abelian Category (EP,q dP,q TP,q) r ' r ' r p,qEz r.::.rO integers p,q,r with have a pair
(ar,Sr)
where (1)
(4)
TP,q r
0
A,
is an object in
of integers, and for every triple
dP,q = 0, r
all
A,
all
p,q,r E 71
A,
r
r
r
such that (3) . w~
th
> r _rOi
h an d were
[Ker (dP,q)/Im(dP-ar,q-Sr)]~ EP,q r r r+l
is an isomorphism:
in the abelian category
p,q,r
dP,q:EP,q ->-EP+ar, q+Sr
we have a map
in the abelian category dP+ar,q+Sr r
r
we
r:=:.r O'
of integers with
EP,q
all
p, q, r E 71
with
r'::' r
o.
Again, as in Example 3, in the above definition of bigraded spectral sequence in the abelian category
A,
no conditions imposed on the integers
all
r'::' r O.
r
and that
a , Sr E Z , r
However, in practice, it is usually true that Sr = -r + 1,
all integers
r.::. r O.
a
r
=
there are
Such a bigraded spectral se-
quence will be called conventional (the motivation for why such a condition should be so important will be clear when we study the spectral sequence of a bigraded exact couple in the next section.)
Thus, a conventional bigraded spectral sequence in
the abelian category
A starting with the integer
multi-indexed family:
(EP,q dP,q TP,q) r ' r ' r p,q,rE7i' r.:=:.rO
rO
is, a
where (1)
EP,q is an object in A, (2) all p,q,r E71 with r .:=:. rOi r EP'q .... EP+r,q-r+l dP,q: is a map in A, all p,q,r E71 with r r r such that (3 ) dP+r,q-r+1 odP,q=O, all p,q,r E71 r .:=:. rOi r r with
r >r i - 0
and where
(4)
TP,q r
[Ker(d~,q)/Im(d~-r,q+r-l) 1 '!E~~i all
p,q,rE71
is an isomorphism: in the abelian category
A,
with
Example 5.
Let
m
be any non-negative integer and let
D = (Zm, +) .
Then as a special case of Example 2, we have the
190
Section 4
~m-graded spectral sequence in any abelian cate-
notion of a gory
A.
This is also called an m-spectral diagram in the abel i-
an category
Thus, an m- spectral diagram for
A.
(ordinary, ungraded) spectral sequence;
m= 0
is an
a I-spectral diagram
is a singly graded spectral sequence; and a 2-spectral diagram is a bigraded spectral sequence. m> 3
An m-spectral diagram for
is a new kind of object, and is sometimes studied in cer-
tain cases. Remark 1.
Example 4, for the special case of conventional bi-
graded spectral sequences;
Example 3, for the special case of
conventional singly graded spectral sequences; and Example 2 are the most important and frequently used kinds of spectral sequences in mathematics. Remark 2.
Let
A be an abelian category and let
(E~,d~,T~)nE~ r~rO
be a conventional singly graded spectral sequence in if we define
A.
Then
then we ob-
tain a conventional bigraded spectral sequence (EP,q dP,q ,p,q) • r ' r ' r p,q,rE~
In this way, conventional singly graded
r~rO
spectral sequences can be regarded as special cases of conventional doubly graded spectral sequences (however, we shall not usually do this).
(The above procedure also allows us to turn
every singly graded spectral sequence in
A,
whether conven-
tiona I or not, into a doubly graded spectral sequence, such that the bidegree of r
~rO.
d** r
has first coordinate
r, each integer
If the procedure is so generalized, then a given singly
graded spectral sequence is conventional iff the associated doubly graded spectral sequence is conventional.)
Graded Abelian Category Remark 3.
191
A be an abelian category such that denumerable
Let
direct sums exist in an exact functor.
A and such that denumerable direct sum is
Then if
(EP,q dP,q TP,q) r 'r 'r
is an arbi-
p,q,rE~
r..::rO trary doubly graded spectral sequence in the abelian category
A,
then we can associate a singly graded spectral sequence by defining:
En = r
Ell
p+q=n
EP,q r'
dn = r
Ell
p+q=n
Tn = r
dP,q r'
Ell
p+q=n
TP,q r'
This procedure turns a conventional doubly graded spectral sequence into a conventional singly graded spectral sequence. Of course, the procedure of Remark 2 is perfectly general (requiring no hypotheses on the abelian category
A);
and a
singly graded spectral sequence can be recovered from its associated doubly graded spectral sequence. n T r
'=
T
n,O r
(Namely,
n,rE~,
all
(Both of these ob-
servations, of course, fail for the, more crude and more special, procedure for passing from doubly graded spectral sequences to singly graded spectral sequences, as described in Remark 3 above.) Remark 4.
Of course, analogous to Remark 2, there is a way of
passing from an ungraded spectral sequence: the abelian category n dn (E r' r,T n) r
n,rE~
r..::rO of degree +1,
A to
a singly graded spectral sequence:
-- n a me ly , d e f'lne Tn = T
r
r'
all
n,r
En = E , r
~ ~,
r
d
n =d r r
and
d* r
is
Again, this pro-
cedure enjoys all the nice properties of the procedure of Remark 2; and, the definition we have given is such that, the singly graded spectral sequence that we have just defined is
Section 4
192
d*
always conventional (since we have insisted that ree
+1,
all
r .:::.r ). O
abelian category
is of deg-
r
Also, analogous to Remark 3, if the
A has denumerable direct sums and if denumer-
able direct sum is an exact functor, then one can associate to (En d n n) r' r,T r n,rEl" an r.:::.rO where we define:
every singly graded spectral sequence: ungraded spectral sequence: E = Ell En, r nEl' r
(Of course,
these two procedures, when they both make sense, for passing from ungraded to singly graded, or from singly graded to ungraded spectral sequences, are not inverse to each other.
Simi-
larly, the procedures of Remarks 2 and 3 above, when they both make sense, are not inverse to each other.) Let us now return to study the general theory of spectral sequences.
That is, we have a fixed additive abelian group
A,
and a fixed D-graded abelian category
A.
spectral sequences in
D
and we are studying
A quick summary is, that essentially
all the results of section 1 go through to this more general situation, without any change in the arguments.
We keep the
same theorem numberings; statements only are given since the proofs are essentially the same.
We also keep the analogous
numbering of Definitions and Remarks. Definition 2'.
Let
D
be an additive abelian group, let
a D-graded abelian category, and let
(Er,dr,Tr)r>r
tral sequence in the D-graded abelian category the integer
rOo
Er ,
i.:::. 0,
two sequences
for each integer
r 2:.rO'
by
Zi (E ), Bi (E ) r r
r 2:. r 0'
quence of maps of degree zero in the category
be a spec-
A, starting with
Then we define, for each integer
induction on the integer of subobjects of
- a
A be
and also a se-
A,
called i-fold
Graded Abelian Category
193
for all integers
r
~
r O.
(The inductive construction is identical, word for word, to Definition 2 of section 2, so we don't repeat it.) Zi(E r )
the i-fold cycles in
daries in
Er'
Er
all integers
i
~
Bi (E ) r
and
the i-fold boun-
all integers
0,
We call
r
~rO'
(The
Remark following Definition 2 of section 1 is also applicable in this situation.) Proposition 1'.
Let
D
be an additive abelian group, let
A
be a D-graded abelian category and let
(Er,dr,Tr)r>r be a - 0 spectral sequence in the D-graded abelian category A, starting
wi th the integer
r O.
Then for every integer
r
Er .
Also, for every integer
~
rOwe have
that
as subobjects of integer 2)
j
~
0,
The map of degree zero "j-fold image":
(j-fold
= Zi+j (E r ) = B,+, (E ) 1 J r
(j-fold all integers integer
j
~
i,j,r 0
~rO
and every
we have that
epimorphism, and that 3)
r
with
i,j~O,
and every integer
I
,
r~rO'
r
~
r ' O
Z, (E ) -+ E
J
r
,
r+J
is an
as subobjects of
Moreover, for every there is induced a
specific isomorphism of degree zero:
(The proof is entirely similar to that in the ungraded case, see
194
Section 4
section 1.) Remark:
Let
D
be an additive abelian group and let
D-graded abelian category. degree zero of
A
Let
AO
all maps of degree zero of all objects of
gory.
AO
be a
be the category of maps of
(consisting of all objects of
seen in section 3,
A
A).
A,
and of
Then as we have
is an (ordinary, ungraded) abelian cate-
When we speak of a "subobject" (or a "quotient-object",
A
or a "subquotient object") of an object belian category
A,
in the D-graded a-
then we mean, as in Definition 5 of section
3, a subobject (or a quotient object, or a subquotient object) of
considered as object in the (ordinary, ungraded) abelian
A
category
AO.
(Therefore, for example, a subobject of
(B,i)
equivalence class of pairs: and
(B',i') iff .3 an isomorphism
i' = i
is an object in
B
is a monomorphism of degree zero, where
i: B .. A
tha t
where
0
is an
A
(B, i) '"
e:B'~B,
e of degree zero,
such
e) •
Remark 2'.
The hypotheses being as in Proposition 1', we have
that
is isomorphic (by means of
Er+l
degree zero)
to
Ker(dr)/Im(d r ).
natural way a subquotient of is a subquotient of
E . r
Er .
T
r'
an isomorphism of
Therefore
Er
itly
such that
A'
is
A" c: A'
Zi(E ) r
and
is in a
Er+l
i.::. 0,
Therefore, for
Er+l
Therefore, by the general theory of
subquotients, there must exist unique subobjects of
A
and such that
A"
is
Er+i
Bi(E ). r
A'
and
= A' /A".
A"
Explic-
(The analogue
of
Remark 3 of section 1 also holds good). Remark 3'.
Under the hypotheses of Proposition 1', if we look
at the corresponding spectral sequence in the dual D-graded category, the i-fold cycles in
Er
constructed in
O
A ,
call it
O
A
Z.
~
(E), r
is the quotient-object of
Er
that corresponds to the
Graded Abelian Category
195
o
subobject
Bi{E ), r
quotient-object of i~O,
Zi{E r ), Lemma 2'.
~
i E
0,
r
~
r O.
Similarly,
B~l (E r )
is the
that corresponds to the subobject
r
r~rO.
Let
D
be an additive abelian group and let
A
be
a D-graded abelian category such that denumerable direct sums (resp.:
denumerable direct products) exist in the D-graded
category
A.
Then
A
is closed under denumerable suprema (resp.:
infima) of subobjects. Proof.
Let
Ao
be the category of all objects, and all maps of
degree zero, of
A.
Then as we have seen in section 3,
closed under denumerable direct sums (resp.:
A
is
products) of ob-
jects as a D-graded category iff the (ordinary, ungraded) abelian category
AO is closed under denumerable direct sums (resp.:
products) of objects.
Lemma 2 (resp.:
Corollary 2.1) of sec-
tion 1 therefore completesthe proof. Definition 3'.
Let
D
be an additive abelian group and let
be a D-graded abelian category.
A
(Er,dr,Tr)r>r be a spec- 0 tral sequence in the D-graded abelian category A starting with the integer
r O.
Then for every integer
1)
Z (E ) = n z. (E 00 r i>O l
of
Er
2)
B
t ),
r.:: r 0'
we define
i f this denumerable infimum of subobjects
exists, and (E
00
Let
r
) =
J B.l
i>O
(E
r
if this denumerable supremum of subob-
),
is called the permanent cycles of is called the permanent boundaries of tegers
r
~
E , r
all in-
rOo
Proposition 3'.
Let
D
be an additive abelian group.
be a D-graded abelian category, let
rO
Let
A
be an integer and let
Section 4
196 (Er,dr,Tr)r>r
-
A starting with the integer
category teger
1)
r
be a spectral sequence in the D-graded abelian
0
~
r 0'
Z (E) 00 r
Z
2)
exists iff
(E)
r-r 0
r0
Zoo (E ) r -+
3)
Z
r-r
I f both
(E)
rO
O
Z (E 00
and
r
rO
E
)
exists, in which case,
under the epimorphism, "(r-rO)-fold
•
exists, in which case,
Boo(Er)
o
Boo (E ) r -+
rO
r
Boo(Er)
o
under the epimorphism,
" (r-r 0) -fold
•
exist as in conclusions (1)
) and
(2) above, then we have that Er
= Zo (E r
Boo (E ) r
~
)
~
...
Zl (E ) r
~
Z (E
rO
)
and
~
..
Bi+l (E r )
as subobjects of 00
E
exists iff
is the pre-image of image" :
Z (E 00
Boo (E ) r
Then for every in-
we have that:
is the pre-image of image" :
rOo
E , r
B (E 00
rO
,~Zi ~
(E ) r
~
Zi+l (E ) r
Bi (E ) r
~
...
~
for all integers
)
~
...
Bl (E ) r r
~
~rO'
~
Zoo (E ) r
BO (E ) r
~
= 0,
And, then
both exist, then for every integer
we have that the epimorphism
r':: r
' O
"(r-rO)-fold image" induces an
isomorphism:
4)
Z (E 00
rO
) /B (E 00
rO
) ":,. Z (E ) /B (E ). 00 r 00 r
(The proof is entirely similar to that of Proposition 3 of section 1). Definition 4'.
Let
D
be an additive abelian group, let
a D-graded abelian category, let (Er,dr,Tr)r>r
category E 00
A
rO
A
be
be an integer and let
be a spectral sequence in the D-graded abelian
0 starting with the integer
exists iff
Z
(E 00
r 0
)
and
B (E 00
rO
)
rOo
Then we say that
both exist, as defined in
Graded Abelian Category
197
Definition 3' above; in which case, we define
From Proposition 3', we immediately deduce Corollary 3.1'.
Let
D
be an additive abelian group, let
be a D-graded abelian category, let
rO
A
be an integer and let
be a spectral sequence in the D-graded abelian (Er,dr,Tr)r>r - 0 category A starting with the integer be any Let r fixed integer Boo(Er)
~.rO.
Then
Eoo
Zoo(E ) r
exists iff both
and
exist, and when this is the case there is induced a can-
onical isomorphism:
(The inverse of that isomorphism being induced by "(r-rO)-fold image". ) Remark 1'.
The hypotheses being as Proposition 1', notice that
(Er,dr'T~l)r>r
is a spectral sequence in the dual D-graded a-
- 0 belian category,
0
A.
1', it follows that:
From the Remark 3' following Proposition If
r
is any integer .:.. r
exists in the given spectral sequence in
A
O
iff
then
' B
00
(E ) r
Z
(E 00
r
)
exists
O
for the dual spectral sequence in A (call this latter o o "BA (E )"). BA (E ) in which case, is the quotient-object of 00 r ' 00 r o BA (E ) = E /Z (E ). Also, in A, 00 r roar given spectral sequence in
A
iff
Z
spectral sequence in the dual category, "ZAo(E )") r
00
Er
in
A,
'
in which case
o
ZAo(E) OJ
zA (E r ) = E r /B 00 (E r ). 00
Definition 4', imply that:
Eoo
r
exists for the dual
(E ) 00
r
O
A
(call this latter
is the quotient-object of
These two observations and exists for the given spectral
198
Section 4
A iff
sequence in the D-graded abelian category
Eoo
exists for
the dual spectral sequence in the dual D-graded abelian category
AO ;
in which case, they coincide.
Remark 21.
Let
D
A be a
be an additive abelian group, let
D-graded abelian category, let
rO
be an integer and let
be a spectral sequence in the D-graded abelian (Er,dr,Tr)r>r - 0 category A starting with the integer Then we have observed, in Remark 21 following Proposition 11, that sUbquotient of of
E
, rO all integers
Clearly
Er
is a
as subquotients
, Then notice that, by Introductior rO Chapter 1, section 5, Corollary 1.4, we have that: The deE
creasing sequence of subquotients an infimum iff the abutment tion 4 1
;
E00
Er ,
admit rO exists in the sense of Defini-
in which case, the abutment
r .:::.rO'
E00
of
E
is that infimum.
(Of
course, this gives another definition of the existence and value of
Eoo'
that is equivalent to Definition 4 1
,
entirely in terms
of infima of subquotients). Definition 51.
Let
D
be an additive abelian group, let A
a D-graded abelian category, let
rO
be
be an integer and let
(Er,dr,Tr)r>r and (IEr,ldr,ITr)r>r be spectral sequences in - 0 - 0 the D-graded abelian category A, starting with the same integer A map of spectral sequences from
into (Er,dr,Tr)r>r - 0 is a sequence (f ) indexed by the inter r.:::.rO f are maps, of arbitrary degrees (a priori r
perhaps differing for different A
from (Ml)
Er
into
0
in the D-graded category
I E r , for all integers
For every integer Id r
r),
fr = fr
0
dri
r
2:. r 0'
r
2:. r 0'
we have that
and such that
such that:
Graded Abelian Category (M2)
For every integer
r 2. r 0'
the diagram:
H(f ) H (Er ,dr ) _ _...;;r,--.;;» H ('E
'" l'r
'"
199
'd)
l'rr'
r
fr+l
-=-'--=---:> 'E
A is commutative.
in the D-graded category Remark 0.1. (fr)r>r
r+l
In practice, most of the maps of spectral sequences
that one encounters, are such that
-- 0
integers
deg(f r ) = 0,
all
r 2. r O.
Remark 0.2.
Let
(1) = (Er,d r " r) r>r and (2) = ('E r , 'dr'" r) r>r - 0 - 0 be spectral sequences in a D-graded abelian category starting with the same integer
r
a map from (1) into (2).
' O
and suppose that we have
(fr)r>r - 0 Then, from Axiom (Ml), we deduce that
deg('d ) +deg(f ) =deg(f ) +deg(d ), r r r r (3)
deg(d ) =deg('d ), r r
i.e.,
that
r~JO.
all integers
Thus, a necessary condition for there to exist a map from the spectral sequence (1) into the spectral sequence (2) is that all integers
r >r
-
sufficient, since if one takes, e.g., ree zero from
E
r
0
.
This condition is also
fr = (the zero map of deg-
all integers
into
then
(fr)r>r is a map from the spectral sequence (1) into the spec- 0 tral sequence (2). Given two spectral sequences in a given 0graded abelian category
A,
we call them of the same kind iff
they start with the same integer deg('d ), r
all integers
r 2.rO'
-- ---
r
' O
and if also
---- ---
deg(d ) = r
By what we have just observed,
two spectral sequences in the D-graded abelian category of the same kind iff there exists a map between them. Notice, also, from Axiom (M2), that if
A
are
Section 4
200
of spectral sequences in the D-graded abelian category deg(f r ) +deg("r) =deg(f + ) +degh )· r r l deg("r) = 0,
then
deg('r) =
this implies that
(4 )
deg (f ) = deg ( f
Let
D
r 0
r
),
all integers
r~rO'
be an additive abelian group and let
graded abelian category. rO
Since
A,
Consider a pair
is an integer and where
A
be a D-
(r, (ar)r>r)'
o
-
where
0
r '::.rO'
E D is a degree, all integers r We will call such a pair a sequence of degrees in the
abelian
~
D.
L'l.
Then we let
Spec.Seq. (r
(a) ) (A) de0' r r~rO note the category, having for objects all spectral sequences
(Er,dr"r)r>r starting with the integer rO in the D-graded - 0 abelian category A, such that deg (d ) = a for all integers r r r':' r ' O
and for maps, all maps of spectral sequences as defined
in Definition 5'. Proposition 0.3.
Let
D
be an additive abelian group, let
be an integer and, for all integers degree. gory
Let
A
r~rO'
let
be a D-graded abelian category.
Spec. Seq. (r O'
(a) ) (A) r r>rO
lYrE D
rO
be a
Then the cate-
has a natural structure as D-
graded additive category. Proof.
We have already observed the category structure.
For
(a) ) (A), by equa0' r r>rO tion (4) we have that deg(f) =deg(f ), all integers r~rO' r rO Define deg(f) = deg(f r ), all integers r ~rO' Then every map
f = (f r ) r>r - 0
in Spec. Seq. (r
becomes a D-graded category. (a) ) (A) r O' r r>r - 0 graded additive structure is obvious. (Namely, define Spec. Seq. (
The D-
Graded Abelian Category
201
are maps with the same domain and range and such that deg(f r ) =deg(gr ), o 0 deg (gr ) = deg (gr) ,
o
and therefore such that all
r 2.r ' O
deg (f ) = deg (f ) r rO fr + gr is defined).
so that
Q.E.D. Remark I'.
Let
(1) = (Er,dr,Tr)r>r
and (2) = ('Er,'dr,'Tr)r>r 0 - 0 be spectral sequences starting with the same integer rO in the
D-graded abelian category
A,
and let
arbitrary degrees), for all integers
fr:E r?. r O.
r
.... 'Er
be maps (of
Then, if Axiom
(Ml) holds, then Axiom (M2) is equivalent to the statement that, r ?.r ' the map fr+l O passing to the subquotients. Hence, if for every integer
spectral sequences, then for every integer that
is induced by
r?. r 0'
fr
by
it follows
f
is induced from f by passing to the subquotients. r rO Therefore a map of spectral sequences starting with the integer in the D-graded abelian category A is com(fr)r>r ' - 0 pletely determined by the initial map f rO Otherwise stated, an alternative, equivalent definition of a map of spectral sequences starting with the same integer in the D-graded abelian category
A,
rO
from (1) into (2), is:
"A map
f:E .... 'E , of arbitrary degree, such that there rO rO rO exist maps f r: Er .... 'Er for all integers r?. r 0 + 1 such that conditions (MI) and (M2) above hold". Example.
The construction of Remark 2 following Example 5 after
Definition 1 of this section can be seen to be related to that of Exercise 3 of section 3 ("change of grading groups, other direction" ) .
In fact, in the notations of Remark 0.2 above, we
have that the construction of Remark 2 is: the construction of a canonical additive imbedding of additive bigraded categories, from
Section 4
202
7lX7lSpec. Seq. (r
7l
(1)
r~rO
0' into
Spec. Seq. (r
(r -r+l) 0"
additive abelian groups p + q.
) (A
r>r - 0
and for all abelian categories
) (A )
7l X7l
A;
for each integer
),
where the homomorphism of is the sum map,
¢:7l x7l-+7l
More generally, for every abelian category
>:7l x 7l -+7l
p + q,
¢(p,q) = A,
denotes the additive homomorphism such that
if again >
(p,q) =
then the construction of Remark 2 following Exercise 5 is
A canonical additive imbedding of bigraded additive categories from 7l x7l Spe .
7l
() ) (A ) 0' O:r r-.::.rO 7lx7l
into for
Seq. (r
Spec. Seq. (r ' (r -r+o: ) ) (A O , r r-.::.rO every abelian category
A,
),
every integer
r 0'
and every
sequence
(O:r)r>r of integers. - 0 .Similarly, Remark 3 following Exercise 5 is related to the
construction in Exercise 2 of section 3 ("change of grading group, additive case".)
Namely, if
A
is any abelian category
such that denumerable direct sums of objects exist and such that denumerable direct sum is an exact functor, then the constructiol of Remark 3 following Example 5, is the construction, for each integer
r ' O
of a specific additive faithful functor of singly
graded additive categories I:
Spec. Seq. (
Spec. se q .(
r O'
r O'
( _ +1) r, r (1)
r>:t - 0
)
r2r O
) (A
7l
),
(A
7lx7l
)
7l
'\IV>
Graded Abelian Category
203
with respect to the additive homomorphism of additive abelian groups
¢:J' XJ' +J'
such that
¢(p,q) =p+q,
all
p,qEJ'.
Similarly, the constructions in Remark 4 following Example 5 after Definition 1, are the construction, for every abelian category
A
1)
and every integer
r
' O
of
A canonical additive imbedding of singly graded addi-
tive categories, J'spec. Seq.
(A)'VV> Spec. Seq. (r rO
(1)
0'
r~rO
)
J' (A ),
with respect to the (unique) homomorphism of additive abelian groups
¢:~+
{a};
and, if the abelian category
A
has denum-
erable direct sums and is such that the functor "denumerable direct sum" is exact, then also the construction of (2)
A canonical additive faithful functor of (ordinary,
ungraded) additive categories, I:
(Spec. Seq. (
Remark 2'.
(2)
Suppose that
= ('Er'~r,ITr)r>r
abelian category pose that
J' () )(A ) {O}'VV> Spec. seq.ro(A). r O' a r r>r - 0 (1) = (Er,dr,Tr)r>r
and - 0 are spectral sequences in the D-graded
- 0 A starting with the same integer
rOo
Sup-
:E + 'E is a map (of arbitrary degree) in the rO rO rO D-graded abelian category A, such that, for every integer r > r, -
0
f
degree as
f
induces a map
rO f
f
r
: Er + 'Er
(necessarily of the same
), by passing to the subquotients. (It is equivarO (Z. (E » C Z. (' E ) and lent to say that, "such that f rO ~ rO ~ rO f (B.(E »CB.('E ), for all integers i~O"). Then, is rO ~ rO ~ rO the sequence (f) necessarily a map of spectral sequences? r r~.r 0 As in the corresponding observation in section ~ the answer is
Section 4
204
in general "no".
Necessary and sufficient conditions for such
a constructed sequence (fr)r~ro
of maps (i.e., a sequence of
maps
r 2rO'
fr:E r "" 'E r , fr
duces
all integers
such that
fro
in-
by passing to the subquotients, all integers
to be a map of spectral sequences, is that Axiom (Mll above hold. Remark 2.1.
Let (1) and (2) be spectral sequences in the D-
graded abelian category
A
starting with the same integer
rOo
Let
(fr)r>r be a sequence of maps as in Remark 2' above- 0 that is, fr:E "" 'Er is a map (of arbitrary degree) in the r
D-graded abelian category fr
is induced from
A,
all integers
r .:.rO'
such that
f
by passing to the subquotients. Then, rO as we have noted, (fr)r>r need not be a map of spectral se- 0 quences, since Axiom (Ml) need not hold. Given such a sequence it is still true that r.::.rOl
gers for
deg (f ) = deg (f ), all inter rO however, it need not be true that deg(d ) =deg('d r r
r.:. r 0'
since Axiom (Ml) is not being assumed.
Therefore
such sequences
(fr)r>r can, and in fact do, exist between - 0 spectral sequences not of the same kind, as long as they start with the same integer
In fact, if
(1) = (Er,dr"r)r>r - 0 are spectral sequences in the D-grade(
and (2) = ('E r , 'dr' "r)r>r - 0 abelian category A starting with the same integer not necessarily of the same kind, then if we let the zero map of degree zero from
Er
into
'E , r
fr
but be, e.g.,
all integers
(fr)r>r is as in Remark 2' (but - 0 is not a map of spectral sequences in the sense of Definition
r .::.rO'
then the sequence
5' unless the spectral sequences (1) and (2) are of the same kind) .
Thus, if
A
is any D-graded abelian category, and
rO
Graded Abelian Category
205
is any integer, then one could speak of "the category of all spectral sequences starting with the fixed integer fixed D-graded abelian category (fr)r>r
A,
rO
in the
with maps all sequences
as defined in Remark 2' above."
That category is an
- 0 additive, in general non-abelian, D-graded category, but it is not very interesting. (r
o'
(ar)r>r)
-
(For every sequence of degrees
in the additive group
Spec. Seq. (
()
ro, a r
) (A)
r>r
cons tructed above is an addi ti ve D-
be an additive abelian group and let
D
Let
graded abelian category.
Let
i
~
and
0,
B.
1.
a map in
Spec. seq'r
(resp.: ~a)
Spec. Seq. rO
in
F',F")
r':: r O.
Then for each
Spec. Seq.
(Therefore i f of degree
(A)
() (A) r O' a r r~rO is f = (f ) r>r r - 0 d, then Zi(f)
r r~rO
A
are maps in F
A.
(a)
0' and
be a D-
are covariant additive functors
from the D-graded additive category into the D-graded category
A
be a fixed integer and let
be fixed degrees, all integers
integer
If
the D-graded category
subcategory-o~ that category).
graded
ar E D
D,
0
d,
of degree
all integers
i
~
0).
are the full D-graded subcategories of
(A)
generated by those spectral sequences
r r.::rO
(a)
Spec. seq'r 0'
(A)
such that
(resp. :
r r.::rO
)) exist, which are D-graded ) and B (E 00 rO rO ) additive categories, then Z (E (resp.: B (E ); E) are 00 rO 00 00 rO covariant, additive functors from the D-graded additive cate-
Boo(Er ); both
o
gories
Z (E 00
F
(resp.:
Proposition 4'.
F',F")
Let
D
into
A.
be an additive abelian group, let and
be an integer and let (1) = (Er,dr,Tr)r>r
( 'E 'd
r
r'
-
(2) =
0
be spectral sequences in the D-graded abelian
'T)
r r>r
rO
0
206
Section 4
A starting with the same integer
category
rOo
Let
f = (f r ) r>r be a map of spectral sequences in the sense of - 0 Definition 5' from (1) into (2). Then the following two conditions are equivalent. is an isomorphism (of arbitrary degree)
(1) in the category f= (fr)r>r - 0
(2)
Remark: f
A.
is an isomorphism of spectral sequences.
Of course, condition (2) of Proposition 4' means that
is an isomorphism in
Spec. Seq. (r 0'
ar=deg(dr)=deg('d r ), Corollary 4.1'.
all integers
(a) ) (A), r r>rO
where
r~rO.
Under the hypotheses of Proposition 4', sup-
pose that the two equivalent conditions (1) and (2) of Proposition 4' hold.
Then
Z (E
If
00
if
Z
(E 00
rO
)
and
rO
)
f
r
: Er -+ 'Er
exists (resp.:
B (E 00
rO
)
exist),
Boo(f): Boo(E r ) -+Boo('E r
(resp.:
o
an isomorphism in the category deg (f r
is an isomorphism, all integers
);
If
Boo(E r
then resp.:
)
o
exists;
Zoo(f): Zoo(E r
resp.:
) -+ Zoo('E r
o
E",(f): Eoo-+ 'E,,)
.
0
is
0 A, of degree equal to deg(f)
).
o
(The proofs of Proposition 4' and of Corollary 4.1' are entirely similar to those of Proposition 4 and of Corollary 4.1 of section 1). Remark 1'.
In the statement of Proposition 4', suppose we weaken
the hypothesis that
"f = (f ) be a map of spectral sequences r r~rO in the sense of Definition 5'" to the weaker assertion, that "(fr)r>r be a3 in the hypotheses of Remark 2' following Defi- 0 nition 5'." Then Proposition 4' and Corollary 4.1' remain valid (where, in condition (2) of Proposition 4', by "isomorphism of
Graded Abelian Category
207
spectral sequences" one means "isomorphism in the D-graded category of all spectral sequences starting with the fixed integer ro
in the fixed D-graded abelian category
A,
with maps all
sequences
(fr)r>r as defined in Remark 2' above.") Of course, - 0 then condition (2) is equivalent to the statement: (2')
fr
is an isomorphism (of arbitrary degree) in the
D-graded category
A, all integers
r
~
rOo
(Notice, that an "(f ) > " as in Remark 2' following Definir r_rO tion 5' induces a map from Zoo(Er ) into Zoo (' Er ) whenever 0
0
both are defined; similarly for
B 00
and
EcO> .
Section 5 The Spectral Sequence of an Exact Couple, Graded Case
This section closely parallels section 2.
We therefore
will use a similar theorem numbering, and we will omit proofs when they are identical to the corresponding proofs in section 2. We let
D
be a fixed additive abelian group, throughout
this section. Definition 1'. V
Let
be an object in
A A
be a D-graded abelian category, let and let
essarily of degree zero) quence of subobjects,
from
(Ker t
sequence of subobjects of
t:V-*V
r
V.
lection of all subobjects of
V
be a map in
into itself. r ~ 0,
),
of
A
(not nec-
Then the se-
V,
is an increasing
If a supremum exists in the colV,
(t-torsion part of
then it is called the t-torsion
L Ker(t r ).
V)
r>O Similarly, the sequence of subobjects,
is a decreasing sequence of subobjects of
V.
If an infimum ex-
ists, then it is called the t-divisible part of (t-divisible part of
V) =
n
V,
r Im(t ).
r>O Definition 2'.
On the other hand, we can consider the inverse
system, indexed by the positive integers, such that i':l,
and such that
t(i+l)~v(i+l) 208
-*v(i)
is the map
V(i) =V,
t,
all
Exact Couple, Graded Case integers
i > 1.
lim(v(i) t(i» i>l
If an inverse limit
the D-graded category
A,
209
exists in
I
"",0.
then we have the natural map:
If the inverse limit exists, then the image of this map, a subobject of
V,
is called the infinitely t-divisible part of
V.
Finally, consider the direct system indexed by the positive integers, such that
V (i) = V,
t (i):V (i)
is the map
->
V (i+l)
this direct
i
~ 1,
t,
and such that i > 1.
If a direct limit of
system exists, then we have the natural map:
If the direct limit exists, then we call the kernel of this map the infinite t-torsion part of Example 1'.
V.
If in the D-graded abelian category
A,
denumer-
able direct products of objects exist, then by Proposition 6 of section 3,inverse limits of inverse systems in the category
A
indexed by denumerable directed sets exist, and also by Corollary 2.1 of section 1 denumerable infima of subobjects of objects of
A
exist.
Therefore, in this case,
t:V
->
V
is any map (of
arbitrary degree), then both the t-divisible part of the infinitely t-divisible part of D-graded abelian category
A
V,
exist.
V,
and
Similarly, if the
is such that denumerable direct
sums of objects exist, then direct limits of direct systems indexed by denumerable directed sets in the category
A
exist,
and also denumerable suprema of subobjects of objects of exist.
Therefore, in this case, whenever
the D-graded category
A
t:V+V
A
is a map in
(of any degree), then the t-torsion
210
Section 5
part of
V
and the infinite t-torsion part of
Example 2'.
Let
A
t:V .... V
both exist.
be a D-graded abelian category, let
be an object and let Then
V
t:V .... V
V
be a map (of arbitrary degree).
is also a map in the dual D-graded abelian cate-
It is easy to see that the t-divisible part, resp.:
gory
t-torsion part; infinitely t-divisible part; infinitely t-torsion part of the map in the dual D-graded abelian category t:V"" V,
exists iff the t-torsion part, resp.:
t-divisible
part; infinite t-torsion part; infinitely t-divisible part of t:V"" V
A·,
exists in the given D-graded abelian category
which case, the t-divisible part (resp.:
in
t-torsion part; in-
finitely t-divisible part; infinite t-torsion part) of
t:V .... V
considered as a map in the dual D-graded abelian category, is the quotient-object in t-torsion part (resp.:
A
of
V,
V/Q,
where
Q
is the
the t-divisible part; the infinite t-tor-
sion part; the infinitely t-divisible part) of
t:V .... V
as a map in the given D-graded abelian category
considere(
A.
That is, under the operation of passing to the dual Dgraded abelian category and then replacing quotient objects by the corresponding subobjects, the notions of nt-divisible part" and nt-torsion part" interchange, and similarly the notions of "infinitely t-divisible part" and "infinite t-torsion part" interchange. Example 3'.
If
t:V""V
D-graded abelian category of
V
is a map (of arbitrary degree) in the A,
and if both the t-divisible part
and the infinitely t-divisible part of
V
exist in the
sense of Definition I', then we always have (infinitely t-divisible part of
VIc (t-divisible part of
V).
Exact Couple, Graded Case
211
(The proof is similar to that of the corresponding assertion in section 2). Example 4'. object
V
If
t:V-+V
is a map (of arbitrary degree) from the
if the t-torsion part of V
A,
into itself in the D-graded abelian category V
and
and the infinite t-torsion part of
both exist as defined in Definition 2', then we always have (t-torsion part of
V)
C
(infinite t-torsion part of
V).
(The proof is similar to that of Example 4 of section 2). Example 5'.
Proposition I'.
Let
A be a D-graded abelian cate-
gory such that denumerable direct sums of objects exist and such that the denumerable direct limit over the directed set of positive integers is an exact functor.
Then if
is a map (of arbitrary degree) from an object
V
then the of
V)
(t-torsion part of
V)
t:V
-+
V
into itself,
and the (infinite t-torsion part
both exist, and
(t-torsion part of
(infinite t-torsion part of
V)
V).
(The proof of this assertion is similar to that of Proposition 1 of section 2).
Example 6'.
Consider the special case, in which the D-graded
abelian category
A is the category of D-graded abelian groups,
D A = {abelian groups} . d
V = (V ) dED' t:V->V
where
be a map in
d td:V -> vd+dO
Let
d V A
V
be an object in
is an abelian group, all of degree
dO'
Then
Then
A.
dE: D.
Let
d
t= (t ) dED'
is a homomorphism of abelian groups, all
where
dE D.
Then explicitly, (1)
(t-torsion part of
V)
d
(T ) dED'
where
T
d
= {v E V
d
such
212
Section 5
that there exists an integer td+(i-l)dO
0
.t d + 2dO
.,
~
i
every d-dO
td-2dO
=
(5
d
)
t d-idO ( v. )
= v },
~
all
where
S
d
d-(i+I)d O (
i
v i +l
~
dE
)
0, such that
(infinite t-torsi6n part of
dE d
= {v E V:
V) = (H
v = va'
For
such that
d
)dED'
where v. E vd-idO ~
and such that i > O.
(t-torsion part of
V)
o.
o.
all integers
= vi'
all
vi E vd-ido,
There exists a sequence of elements
for every integer t
v d + idO },
in
dEO'
(infinitely t-divisible part of
Hd = {v E vd:
( 4)
=0
td(V)
0
V)
such that
there exists an element
0,
t o o
(3)
t d + dO
0
(t-divisible part of
(2)
i >0
V),
this latter by Proposition 1'. Also, in the category of D-graded abelian groups, if d
B
A = (A )dEO' f:A .... B
= (B d ) dEO
is a map with
fd:Ad .... B d + e
are D-graded abelian groups, and if e = deg (f) ,
so that
d
where
f= (f )dED'
is a homomorphism of abelian groups, all
dE D,
then (5)
d
Ker f = (Ker (f )) dEo'
(where
"Ker fd",
and
"1m fd-e"
1m f = (Im(f
d B = {B )dEO
) )dEO
denote the usual kernels and images
of the homomorphisms of abelian groups). and
d-e
Also, if
are D-graded abelian groups, and if
d
A = (A ) dEO is
eEO
a degree, then (6)
An additive relation
simply an indexed family Ad
lation from (i.e., where Ad x Bd +e ,
all
Rd
into
R
from
d
(R )dEO'
d+e B ,
all
A
into
where
B Rd
of degree
e
is
is an additive re-
dEO
is an additive subgroup of the abelian group dEO).
By Corollary 5.1 of section 3, the Exact Imbedding Theorem
Exact Couple, Graded Case
213
for D-Graded Abelian Categories, every D-graded abelian category that is a set admits an exact
imbeddin~
of D-graded abelian
categories, into the category of D-graded abelian groups.
This
result can be used, in the same fashion as the usual Exact Imbedding Theorem for (ordinary, ungraded) abelian categories, to prove certain theorems that are
"finite"
(i.e., that do not
involve infinite constructions) in arbitrary D-graded abelian categories, by simply verifying them for the case of, the specific D-graded abelian category, the category of D-graded abelian groups.
For example, most of the theorems in section 4 can be
so handled (e.g., the construction by induction of the "r-fold cycles", the "r-fold boundaries", and of the epimorphism, "rfold image", all integers
r
~
0,
given in Definition 2' of sec-
tion 4; or Proposition I' of section 4, etc.) in this section, in the proofs of:
The same is true,
Proposition 2'; in Defini-
tion 4'; Corollary 2.1'; Corollary 2.2'; and e.g., in the proofs of conclusions (lr) and (2r) of both Corollary 3.1' and Corollary 3.2'; - but not when such concepts as "infinite direct sums", "infinite direct products", "infinite suprema of subobjects", "infinite infima of subobjects", "t-divisible part", "t-torsion part", "infinitely t-divisible part", "infinite t-torsion part", or any other construction involving infinite direct or inverse limits is involved.
The reason why the Exact Imbedding Theorem
doesn't apply in that case, is that exact imbeddings do not, in general, preserve such infinite constructions (e.g., in general do not preserve "infinite direct sums", "t-divisible part," etc.). In the theorems noted below, which are parallel to theorems in section 2, the proofs that are left out are always virtually
Section 5
214
the same as the corresponding assertions in section 2.
When a
proof of a corresponding assertion in section 2 uses the (ordinary, ungraded) Exact Imhedding Theorem to reduce the proof to the case of abelian groups, the proof of the assertion in this section uses the Exact Imbedding Theorem for D-Graded Abelian Categories (i.e., Corollary 5.1 of section 3) to reduce the proof to the case of D-graded abelian groups.
(Similarly for
the theorems in section 4 that are parallel to theorems in section 1). Definition 3'.
Let
A
be a D-graded abelian category.
exact couple in the D-graded abelian category
A
Then an
is a diagram:
t
\)V
(1)
E
in the D-graded category
A
(in which the maps
t,h,k
can have
arbitrary degrees), such that we have exactness at each of the three corners.
That is, it is a pair of objects
D-graded abelian category h:V-+-E
and
Ker h,
Im h
k:E-+-V,
= Ker
Proposition 2'.
k, Let
A,
A,
in the
t:V -+- V,
of arbitrary degrees, such that
1m t=
Im k = Ker t. A
be a D-graded abelian category, and
let (1) be an exact couple in exact couple in
together with maps
V,E
A.
Then there is induced another
215
Exact Couple, Graded Case
called the derived couple of the exact couple (I), such that VI = 1m t, maps t,
tl,h
El = (Ker d) / (1m d), l
and
kl
where
d =h
0
k,
and where the
are induced, respectively, from the map and the map
the additive relation
k,
by passing
to the 3ubquotients (as defined on the next to the last page of section 3).
In particular,
deg(t ) =deg(t), l
deg(h ) =deg(h)l
deg(t),
deg(k ) =deg(k). l (The proof is entirely similar to that of Proposition 2 of
section 2). Definition 4'.
Let
A
be a D-graded abelian category, and let t
(1)
be an exact couple in the D-graded abelian category for each integer
r > 0
abelian category
A,
A.
Then
we define an exact couple in the D-graded which we call the r'th derived couple
of the exact couple (1), and denote:
each integer
r > O.
The construction is by induction on
r.
The zero'th derived couple of (1) is defined to be the derived couple (1). teger
r
~
0,
Having defined the r'th derived couple for any indefine the
(r + 1) 'st derived couple of (1) to be
the derived couple, as defined in Proposition 2', of the r'th derived couple of (1).
216
Section 5
Notation: r
.:.0,
We will write
whenever
object
V
trV
t:V->-V
for
1m (tr:v ->- V),
all integers
is a map (of arbitrary degree) from an
A.
into itself in a D-graded abelian category
By induction on
r,
Corollary 2.1'.
Let (1) be an exact couple in the D-graded
abelian category
we deduce,
A.
Then for each integer
derived couple (lr) of (1) r V =trV=Im(t ), Er
~
0,
the r' th
and
k :E ->- V r r r
is such that
a subobject of
r
r
is a subquotient of
V,
E,
and such that the maps
h :V ->- E r r r
are induced, by passing to the subquotients, respectively by the t:V->- V,
map
the additive relation
k: E ->- V, all integers
r> 0.
deg (h ) = deg (h) - r • deg (t) r r> 0.
and the map
In particular, and
deg (k ) = deg (k) , r
Also,
(therefore
deg (t ) = deg (t) , r
where d
r
0
d
r
= 0),
all integers
all integers d
r
=h
r
0
k
r
r> 0.
The proof of the Corollary follows immediately from the Proposition. Remark 1': (1)
We might also picture the r'th derived couple of
as:
where
It
til,
"h
0
t-r",
and
D-graded abelian category quotients by the map the map
k,
t,
respectively.
It
k"
denote the unique maps in the
A deduced by passing to the subthe additive relation
and
Exact Couple, Graded Case Corollary 2.2'.
Let (1) be an exact couple in the D-graded
abelian category all integers
217
r >
A,
o.
and let (1 ) r
be the r'th derived couple,
Then for each integer
r >0
we have the
short exact sequence
o +-
[(Ker t)
n
in which the maps by
hand
k,
(trV) 1
"h"
<~ Er ~
and
"k"
[
tr~
(V/Ker t· (V/Ker t
)
]"'-0,
are the unique maps induced
respectively, by passing to the subquotients
(and therefore have the same degrees as
hand
k,
respec-
tively) . (The proof is entirely similar to that of Corollary 2.2 of section 2.) Remark'
The short exact sequence (*r) of Corollary 2.2' is
such that, the objects at the right and left depend only on and the endomorphism
t
object in the middle is
(of arbitrary degree) of E . r
"a sort of computation" of
Vi
Th(refore the sequence E
in terms of
r
V
and
V
yet the (* r) gives t.
(Of
course, this computation is not perfect, since it is only a short exact sequence). Definition 5'.
Let
A
be a D-graded abelian category and let t
(1)
be an exact couple in the D-graded abelian category
A.
Then
we associate with the exact couple (1) a spectral sequence (Er,dr,Lr)r>r' starting with the integer - 0 abelian category A, as follows. Let Er
0,
in the D-graded
be the object in the
Section 5
218
r'th derived couple of
(1)
as defined in Definition 4',
(as in Definition 4'). in Corollary 2.1', we have that Let Ker (d ) lIm (d ) r r
onto
(Er,dr,Tr)r>O
A,
category
E + , r l
d
0
r
d
r
= 0,
be the identity mapping from
Tr
all integers
r> O.
Then
is a spectral sequence in the D-graded abelian starting with the integer
abelian category ':
Then as noted
and that
O.
the spectral sequence of the exact couple (1)
Remark
r:"O,
in the D-graded
A.
As we have noted in section 4, a spectral sequence
in the D-graded abelian category
A,
starting with a given in-
teger, by re-indexing, can be re-interpreted as a spectral sequence in the D-graded abelian category other integer.
A starting with any
In particular, given the exact couple (1) in an
arbitrary D-graded abelian category, and given any fixed integer r
' O
we can regard the spectral sequence of the exact couple (1)
as starting with the integer
r
' O
by re-indexing the spectral
sequence of (1), as defined ill Definition 5'; we obtain Definition 5.1'.
Let (1) be an exact couple in the D-graded
abelian category
A.
Then the spectral sequence of the exact
couple (1) re-indexed to start with the integer
rO
spectral sequence in the D-graded abelian category with the integer
where
Er,dr,T r
r
is the
A starting
' O
are as in Definition 5' above, all integers
r > O.
(The reason for our inclusion of Definition 5.1' is that we shall actually have occasion, in studying bigraded exact couples
Exact Couple, Graded Case
219
and their spectral sequences, occasionally to regard spectral sequences as being so re-indexed. to start usually with or
2.
rO = 1
The motivation is, in order to make the resulting bi-
graded spectral sequences conventional in the sense of Example 4 of section 4). The spectral sequence of an exact couple, graded case, was first introduced in [ECJ, for certain D-graded abelian categories and certain
D.
The next theorem describes explicitly the r-fold cycles, r-fold boundaries, permanent cycles, and permanent boundaries in the spectral sequence of an exact couple in a D-graded abelian category. Corollary 3.1'.
Let
D
be an additive abelian group and let
A be a D-graded abelian category.
Let
t
(1)
be an exact couple in the D-graded abelian category (Er,dr,Tr)r>O so that (1)
EO = E.
Then
Zoo(EO)
V)
exists, then the per-
exists, and we have that
Zoo (EO) = k -1 (t-divisible part of (lr)
Let
be the spectral sequence of the exact couple (1),
If the (t-divisible part of
manent cycles
A.
Always, for every integer
r
~
V). 0,
we have that
Section 5
220 (2)
If the
nent boundaries
(t-torsion part of Boo (EO)
V)
exists, and we have that
Boo (EO) = h (t-torsion part of (2r)
Always, for each integer
Corollary 3.2'.
exists, then the perma-
V). r
~
0,
we have that
Under the hypotheses of Corollary 3.1', we have
that, always, r > O.
all integers If the (t-divisible part of
V)
exists, then also
(t-divisible part of
V)
n Ker
t.
Always, we have [Ker(tr:V+V)] +tV. If the (t-torsion part of
V)
exists, then also
(t-torsion part of Corollary 3.3'. both E
Boo(EO)
Under the hypotheses of Corollary 3.1', if
and
= EO = Zo (EO)::::;)
V) + tV.
Zoo(EO)
exist, then we have that
Zl (EO)::::;)···::::;) Zr (EO)::::;) ... ::::;) Zoo(EO)::::;) Ker k
=
Im(h) ::::;) Boo (EO) ::::;) ... ::::;) Br (EO) ::::;) ... ::::;) Bl (EO) ::::;) BO (EO) = O. (The proofs of Corollaries 3.1', 3.2', and 3.3' are analogous to the proofs of the corresponding assertions in section 2). Remark 1'.
In Corollary 3.3', if either
Boo(EO)
or
Zoo(EO)
or both do not exist, then the conclusion of Corollary 3.3' re-
221
Exact Couple, Graded Case mains valid, if we simply delete the single occurrence of liB (E ) II 0
00
or of
'
or both in the conclusion, which-
ever or both do not exist. Remark 2'.
In Corollary 3.1', conclusion (1), a sufficient con-
dition for
II
Z
(E 00
divisible part of
0
)
II
to exist is given, namely that the
V)
exists.
This result can be improved.
Namely, necessary and sufficient conditions for
Zoo(EO)
exist is that the decreasing sequence of subobjects of Ker (t)
n
r ~ 0,
(trV),
(t-
have an infimum,
And, when that infimum exists,
Zoo(EO)
to V,
n [(Ker t) n (trV»). r>O is-always the pre-image
n [(Ker t) n (trV»). A similar improvement in r>O conclusion (2) of Corollary 3.1' holds. Namely, necessary and under
k
of
sufficient conditions for
Boo(EO)
to exist is that the inV, (tV) + [Ker (tr:v ->- V) ) ,
creasing sequence of subobjects of r > 0,
L [(tV) + Ker (tr:V -+ V»). And, when r>O Boo(EO) -is always the image under h of
have a supremum,
this is the case,
I [(tV) +Ker(tr:v->-V»). r>O We take the next theorem seriously.
this supremum:
Theorem 4'.
Boo(EO) =h(
Let t
(1)
be an exact couple in the D-graded abelian category that the V)
(t-divisible part of
both exist.
V)
and the
A.
Suppose
(t-torsion part of
of the exact couple (1)
(E ,d ,1 )r>r r r r - 0 in the D-graded abelian category A, we
have that
Also, we have the short exact sequence
Eoo
Then, for the spectral sequence
exists.
in the D-graded abelian category
A:
222 (*)
Section 5
V)l~Eoo ~
O-<-[(Ker t)f"'i (t-divisible part of V/ (t-tor sion part of V)] f -V:':+-),) -<- 0 , [-:-t-';(-':-v=-';(;-:=t'---:t:':o:':r:":s:'::i;:"=o:":n.:........lp;:;';a=:r=-t;="-o=7
in which the maps
"h"
and
"k"
passing to the subquotients.
are induced by
In particular,
hand
k
by
deg("h") = deg h,
deg("k") =deg(k). (The proof is entirely similar to that of Theorem 4 of section 2). Remark I'.
We will call the rightmost group in the short exact
sequence (*), E"" (*),
which is a subobject of
or sometimes the direct part of
Eoo'
The leftmost group in will be called the
or sometimes the inverse part of
that the right part of that the left part of Remark 2'.
the right part of
E",.
which is a quotient-object of
left part of
E""
Eoo Eoo
is a quotient-object of is a subobject of
E . 00
V,
Notice and
V.
As in the corresponding Remark in section 2, we ob-
serve that, if (1) is an exact couple in the D-graded abelian category
A,
then we have a dual couple,
(1°),
which is an
exact couple in the dual D-graded abelian category couple (1) in the D-graded abelian category theses of Theorem 4' iff dual couple (1°) abelian category
O
A
A
AO.
The
obeys the hypo-
in the dual D-graded
obeys the hypotheses of Theorem 4'.
When
this is the case, then by Theorem 4' we have the short exact sequence (*) - and by Theorem 4' applied to the dual couple (1°) in the dual D-graded abelian category short exact sequence,
(*0),
"written backwards".
That is,
with
E",
for
°
(1 )
in
AO. Eoo
AO (*0)
we have a similar is simply (*)
for (1) in
A
coincides
(so the middle terms of (*) and (*0)
Exact Couple, Graded Case coincide), and the left (resp. :
223
right) part of
coincides with the right (resp. : left) part of
Eoo E
for (1) for
In particular, the dual concept of the "right part" of the "left part" of
E00'
and converselYi while
E
00
(1°) •
E
00
is
itself is
"self-dual" . Remark 3 of section 2 does not generalize very readily to D-graded abelian categories (unless the map
t:v
-+
V
is of deg-
ree zero, which is certainly not always the case in the most important applications). Remark 4'.
Remark 4, through the end of Corollary 4.1, gener-
alizes word for word to gories.
exact couples in D-graded abelian cate-
We won't write down the generalization (but we will re-
fer, e.g., to "Corollary 4.1''', which is Corollary 4.1 of section 2, with the single change in statement: "Theorem 4'. ")
"Theorem 4" to
(The Adams spectral sequence, noted at the end
of Remark 4 of section 4 occurs really in a graded category, so that portion of Remark 4 of section 2, technically speaking, actually belongs here). The analogues of Remarks 5 and 6 after Theorem 4 of section 2 go through to
exact couples in D-graded abelian categories,
essentially without change.
(The only changes necessary are:
"Corollary 3. i" by "Corollary 3. i ' " ,
i = 1,2,3,
and delete the
one occurrence of "Theorem 3" in Remark 6). Definition 5'.
Let
D
be an additive abelian group and let
be a D-graded abelian category. t (1)
Let
A
224
Section 5
and
t' V'
~V'
~}I
(2)
E¥,
be exact couples in the D-graded abelian category map of exact couples from (1) into (2) is a pair g:V-+V'
and
f:E+E'
D-graded category t'og=got, Proposition 5.0.
A,
Then a
(g,f)
where
are maps (of arbitrary degrees) in the such that
h' og=foh, Let
A.
D
k'of=gok.
be an additive abelian group.
Let
A
be a D-graded abelian category and let (1) and (2) be exact couples in the D-graded abelian category
A.
Then the following
two conditions are equivalent: (1)
There exists a map of exact couples from the exact
couple (1) into the exact couple (2). (2)
(a)
deg(t)=deg(t ' ),
and
(b)
deg (h) + deg (k)
Proof:
=
Suppose (1), and let
deg (h I (g,f)
)
+ deg (k I
)
•
be a map of exact couples
from the exact couple (1) into the exact couple (2). t'og=got,
h' og=foh
and
k'of=gok.
(3)
deg (t ') + deg (g) = deg (g) + deg (t) ,
(4)
deg(h') +deg(g) =deg(f) +deg(h),
(5)
deg(k') +deg(f) =deg(g) +deg(k).
Equation (3) implies (2) (a). additive abelian group (6)
D
Then
Therefore,
and
Adding equations (4) and (5) in the
yields
deg(h') +deg(k') +deg(g) +deg(f) deg (h) + deg (k) + deg (g) + deg (f) ,
Exact Couple, Graded Case which implies (2) (b). holds. to
Conversely, suppose that condition (2)
Then let
9
be the zero map of degree zero from
and let
f
be the zero map of degree
V',
from
225
E
into
E'.
V
in-
deg(h')-deg(h)
Then by construction, equation (4) holds.
By (2) (a), equation (3) holds, and by (2) (b), equation (6) holds. Subtracting equation (4) from equation (6) we deduce that equation (5) holds. f
Therefore equations (3), (4) and (5) hold.
are zero maps (of various degrees), t 'og,
Since
and
9
h' ° g,
f
rees).
Therefore, equations (3), (4) and (5) imply, respectively,
0
k' ° f
h,
that
t' og=got,
fore
(g, f)
and
go k
h' og=foh
got,
are zero maps (of various deg-
and
k' of=gok.
And there-
is a map of exact couples.
The last proposition motivates the following definitions. Definition 5.1.
Let
D
A
be an additive abelian group and let
be a D-graded abelian category.
If (1) and (2) are exact couples
in the D-graded abelian category
A,
and (2) are of the same kind iff
deg (t) = deg (t' )
then the exact couples (1) and
deg (h) + deg (k) = deg (h' ) + deg (k' ) . Definition 5.2.
Let
D
be a D-graded abelian category. T,pED).
let in
EC p,T
(A)
and such that
A
be an additive abelian group and let Let
T
Then we define a category
and
p
EC p,T
be degrees (i.e., (A) •
are the exact couples (1) such that deg (h) + deg (k) = p.
The maps in
The objects
deg(t) = T EC
(A) are p,T the maps of exact couples, as defined in Definition 5' above.
One way of interpreting Proposition 5.0 is that, if an additive abelian group and if gory,
D
is
A is a D-graded abelian cate-
then the category having for objects all exact couples in
the D-graded abelian category
A, and for maps all maps of exact
226
Section 5
couples in the sense of Definition 5', splits up into the disjoint union pairs
(or direct sum) of the categories
EC
p,T
for all
(A)
(P,T) ED x D. Let
Remark
(g,f)
be a map from the exact couple (1)
the exact couple (2) in the D-graded abelian category
A.
into Then
from equation (4) in the proof of Proposition 5.0, we have that deg (g) = deg (f) + deg (h) - deg (h') .
(4')
Therefore, the degree of either of
f
or
9
determines the
degree of the other. Corollary 5.0.1. A
Let
0
be an additive abelian group and let
be a D-graded abelian cabegory. the category
P, TED,
rees
EC
p,T
Then for every pair of deghas a natural structure
(A)
as D-graded additive category. Proof:
If
(g, f)
is a map in
deg(g,f) =deg f. ECp,T(A)
Then if
EC
(g,f)
p,T
then define
(A),
and
(g',f')
are both maps in
with the same domain, range and degree, say from the
exact couple (1) into the exact couple (2), then by definition deg f=deg(g,f) =deg(g',f') =deg f', the last Remark,
deg 9 = deg f + deg h - deg h' = deg f'+ deg h-
deg h' = deg g'. and
Therefore
(g+g',f+f')
Remark:
EC
p,T
9 + g'
is a map in
domain, range and degree as readily that
and by equation (4') of
(A)
and EC
(g,f)
P,T
f + f' (A),
and
both make sense,
again with the same
(g',f').
It follows
is a D-graded additive category.
Of course, the D-graded additive category
EC
P,T
(A)
as defined in Definition 5.2, is almost never aD-graded abelian category. If (1) and (2) are exact couples in the abelian category
A,
and if
(g,f)
is a map of exact couples in the sense of
Exact Couple, Graded Case Definition 5' P
and
T
t:;
227
(by Proposition 5.0, it is equivalent to say: EC
if (1) and (2) are objects in
D,
(g,f) is a map in
EC
then
(A) "),
p,T
p,T
of (1) and (2) are in
EC
P,T
induces a map, by
(g, f)
(A),
ECp_T,T(A).
and if
(A)
passing to the subquotients, on the derived couples. that, if (1) and (2) are in
"If
Notice
then the derived couples
(This is because, in the
derived couple:
of the exact couple (I), we have that
kl
is induced by
k,
so
deg (k l ) = deg (k), while h is induced by the additive relation: r 0 r- l by passing to the subquotients, so that
that
h
t
deg (hI) = deg (h) - deg (t) ).
The assignment, "derived couple",
therefore is a covariant, additive functor of additive, D-graded categories from
EC
p,T
is of degree
(g,f)
d
in
(gl,f ) l
then the map
into
(A)
EC
(resp.:
deg
(f) ,
g)
p,T
P-T,T
fl
(g,f)
and therefore
gr'
d = deg f),
on the derived couples
(resp.:
gl)
deg (g, f) r
~
0,
= deg
a map
f
are induced by
resp.:
fr
(g, f)
of degree
is induced by
(gr,f ) r
g,
resp.:
d
r
~
0,
and every
p, TED,
of
of degree f,
passing to the subquotients) on the r'th derived couples. fore, for each integer
deg(f ) 1
= deg (f 1 ) = deg (gl' f l ) ) .
exact couples therefore also induces a map (and
if
by passing to the subquotients, so that
By induction on
d
(Notice that if
(A).
(i. e.,
(A)
induced by
has the same degree d- since f
EC
by There-
we have a co-
variant additive functor of D-graded additive categories, r'th
228
Section 5
derived couple, from if
(g,f)
into
EC p ,1(A)
is a map of degree
d
EC
(A).
Therefore,
P- r 1,1
from the exact couple (1)
into the exact couple (2) in the D-graded abelian category then there is induced a map, of the same degree
d,
A,
in the
sense of Definition 5' of section 4, of the associated spectral sequences (which start with the integer zero) in the abelian category
A.
Explicitly, the induced map of spectral sequences
is the sequence on the r'th derived couples,
r> O.
We have proved Proposition 6. A
Let
D
be an additive abelian group, and let
be a D-graded abelian category.
Let
p, 1
i;:
D.
Then the as-
signment which to every exact couple t (1)
in
(E ,d ,1 r )r>0' r r is a covariant, additive functor of D-graded additive categories, from
EC p ,1(A)
EC
p,1
Example 1.
associates its spectral sequence
(A) Let
into D
Spec. Seq. (0 ( _ ) ) (A). , P rt r> 0 be an additive abelian group, let
A
be a
D-graded abelian category and let t
(1)
be an exact couple in the abelian category derived couple
A.
Then we have the
229
Exact Couple, Graded Case "t" tV--·-·-·-~tv
It
/
l "k'\ / : ' h t - "
(1' )
El where, respectively, k and
"ht- l "
"t"
is induced by
is induced by
fh
t,
(f )-1 t '
0
"k"
is induced by
by passing to the sub-
quotients. The exact couple (1) defines an exact couple, call it (1)°, in the dual D-graded abelian category
where
VO = V,
EO = E,
to = t,
hO = k
couple of the exact couple (1)°
in
and O
A
k
O
= h.
The derived
is of the form
litO"
(V/Ker t)
) (V/Ker t)
"k~/hO(tO)-l" El
where, respectively, induced by
f
0
hO abelian category
(f
"to"
1:9
) -1
O
A
is induced by and
"ko"
to,
"ho(to)-l"
is induced by
k
by passing to the subquotients.
the exact couple (1°')
as an exact couple in
A,
exact couple II
ttl
(V/Ker t)
>(V/Ker t)
"t-l~/h" El
O
is
in the Rewriting
we obtain the
230
in
Section 5 the O-graded abelian category
"h" and
(r t)
-1 0
"t-lk"
r k'
A,
in which the maps
are induced, respectively,
by
by passing to the subquotients.
exact couple
is in
(1)
EC
p,
T
(A). P-T,T morphism of
g: (V/Ker t) ~ tV
Let t,
exact couples
and (1
0
,0)
D-graded additive category degree zero:
If the original
(1 0
,0)
are both in
be the factorization iso-
an isomorphism of degree
(l)
t, hand
(A) - i.e., if P = deg h + deg k,
T = deg t - then the exact couples (1') and EC
"tn,
T = deg (t).
Then the
are canonic,ally isomorphic in the ECp_T,T(A),
through the map of
(g, idE ). 1
Remark: quence
By Proposition 6, it follows that every spectral se(Er,dr,Tr)r>O
in the O-graded abelian category
A,
starting with the integer zero, that comes from an exact couple, has the property that there exist degrees
P
and
,
in
0
such that (1)
Of
deg(d ) = P - n, r
cou~se,
P
and
T
all integers
r> O.
are uniquely determined by these proper-
ties. In general, given a spectral sequence
(Er,dr,Tr)r>O
starting with the integer zero in a O-graded abelian category A,
and if
P
and
TEO,
then we will say that the spectral
sequence is of type
(p,,)
all integers
Then clearly, the spectral sequences of
type
(p,T)
r > O.
iff condition (1) above holds for
in the O-graded abelian category
the objects in
Spec. Seq.
(0
(_)
, P r, r>O
)
(A).
A
are precisely
Therefore, we will
sometimes denote this latter O-graded additive category by Spec. seq.P"(A). Then Proposition 6, in this notation, is equivalent to
Exact Couple, Graded Case saying that, for every pair every exact couple in quence, is a
which T
(A)
associates its spectral se-
EC
p,T
into
(A)
A special case of the last Remark is the case in is the additive group of integers
0
= O.
p,T
the assignment which to
covariant, additive functor of D-graded additive
categories from Example 2.
EC
p,T ED,
231
Then if
A
is a
(;r ,+),
p
=1
;r-graded abelian category, the objects
1 0 of Spec. Seq. ' (A)
are precisely all spectral sequences
all integers
Also, the objects of
r> O.
EC1,0(A)
of this Example are all exact couples (1) in the abelian category Example 2.1.
Let
gory, and let
A
such
S
and
that
deg(t) =0,
in the case
;r-graded
deg(h)+deg(k)=+l.
be an (ordinary, ungraded) abelian cate-
A = S;r,
the
;r-graded abelian category of all
singly graded objects in the abelian category
S.
Then Example
2 above applies. Notice that in this case the spectral sequences
in
A = S;r
are what we have called in section 4 the "singly
graded spectral sequences in the abelian category objects of
Spec. Seq.
I 0 ;r ' (S )
S",
and the
are what we have called the"con-
ventional singly graded spectral sequences in the abelian category
S
starting with the integer zero".
couples in the
;r-graded abelian category
We will call the exact S;r,
graded exact couples in the abelian category jects of
the singly S,
and the ob-
the conventional singly graded exact couples
in the abelian category
S.
Thus, a very special case of Propo-
sition 6, is that, for every abelian category
S,
we have the
functor of singly graded additive categories, "associated spectral sequence", from the category of conventional singly graded
Section 5
232
S
exact couples in the abelian category
into the category of
conventional singly graded spectral sequences starting with the
S.
integer zero in the abelian category Example 3. which
Consider the special case of the last Remark in is the additive group
D
any integer.
Then let
(:l x :l , +).
p = (rO,-r
O
+ 1)
and
Suppose that
r0
l = (-1,+1).
In
is
this case, it is the custom to re-index spectral sequences in Spec. Seq.P,l
so as to start with the integer
(A)
A
More precisely, let
be a
rOo
(:l x :l)-graded abelian cate-
gory (that is, a bigraded abelian category), and let integer.
be an
Then we have a natural isomorphism of bigraded addi-
P
Spec. Seq. '
tive categories between Spec. Seq. (r
(r -r+l)
= (-1,+1).
) (A),
l
(A)
where
and
P = (rO,-rO+l)
and
r>r
0"
1
rO
- 0
(Namely,
Spec. Seq.P,1 (A)
Spec. Seq. (0 ( _ ) ) (A). If , P r1 r> 0 then define the corresponding object of Spec. Seq. ( (E r r
o
,d _ r r
( _ +1) ) (A) r O' r, r > r_rO
0
,1 _ r r
)r>r')
0
to be the spectral sequence:
Composing this isomorphism of
- 0
(:l x &?)-graded additive categories with the functor of Proposi-
tion 6, we see that: For every teger
r
' O
(:l x 7l) -graded abelian category
we have an additive functor of
A
and every in-
(:l x7l)-graded addi-
tive categories, "associated spectral sequence", from the category
EC
(rO,-rO+l), (-1,+1)
Spec. Seq. (
r O'
Spec. Seq. (r
( _ +1) r, r (r -r+l)
0" (Er,dr"r)r>O
> r_rO
(A) ) (A).
into the category Notice also that the objects of
) (A) consist of all spectral sequences r>r - 0 starting with the integer rO in the bigraded
Exact Couple, Graded Case abelian category gers
A,
(r,-r+l),
deg(d r )
such that
233
r::..r o.
Example 3.1.
Let
13
be an (ordinary, ungraded) abelian cate-
A = S&'x&',
gory, and let
the
(&' x &') -graded abelian category of
s.
all bigraded objects in the abelian category 3 above applies. in
all inte-
A =SlX&,
Then Example
Notice that in this case the spectral sequences
are what we have called in section 4 the "bigraded
spectral sequences in the abelian category is any integer, Spec. Seq. (r
13",
and that if
then the objects of
(r -r+l) 0"
) (13 r> r
-
&,x&'
)
are what we have called the
0
"conventional bigraded spectral sequences in the abelian category
13
starting with the integer
r
O· "
We will call the exact
couples in the (&' x &') -graded abelian category
S&'x&' ,
the bi-
graded exact couples in the (ordinary, ungraded) abelian cate~
S.
A bigraded exact couple in the abelian category
will be called conventional if there exists an integer that the exact couple is an object in
EC
13
rO
such
(rO,-rO+l), (-1,+1)
(SlX&').
(If the exact couple is the exact couple (1), then it is equivalent to say that: where
(Y, 6),
"if
deg(t) = (-l,+l),
y + 6 = + 1" . )
and
deg(h)+deg(k)=
More specifically, a bigraded exact
couple in an (ordinary, ungraded) abelian category
13
will be
called conventional starting with the integer
rO if the exact lx&' couple is an object of EC ). Then, by (ro,-rO,+l) , (-1,+1) (13 Example 3 above, in the case in which the bigraded abelian category
A
is the category of all bigraded objects in the fixed
(ordinary, ungraded) abelian category
S'
A = Slx&',
we have
that: For every (ordinary, ungraded) abelian category
13,
and
Section 5
234
every integer
r ' O
we have the canonical functor of bigraded
additive categories, associated spectral sequence, from the
(B~x~) of all (rO,-rO+l), (-1,+1) conventional bigraded exact couples in the abelian category B
bigraded additive category
starting with the integer category
Spec. Seq.(
EC
r ' O
into the bigraded additive
( _ +1) ) (A) of all conventional r O' r, r r>r bigraded spectral sequences in the ~belian category B starting with the integer
rD.
Section 6 Filtered Objects
Definition 1.
A is a pair
object in in
A,
F p (A)
::::>
F p+l (A) ,
A,
If
all
(A,F*A)
all
p
(A,F*A)
into
(B,F*B)
(B,F*B)
(A,F*A)
FpA,
is an object
is a subobject of
A,
We sometimes say that the
~
filtered
are filtered objects in the
A, then a map of filtered objects from is a map
A,
the abelian category If
f:.~.
A
p E~ . and
abelian category
where
F A p
p<=;Y
is a filtered object" and call
piece of
A,
(A, (F A) E) p p ~
and where for every
such that "A
A be an abelian category. Then a filtered
Let
f:A->-B
such that
from
A
f(FpA)CFpB,
into all
B
in
pE;y.
is a filtered object in the abelian category
then define GA=FA/F+IA,
P
all integers object
A,
P
p.
P
GpA
is the
all integers
p.
~
graded piece of the filtered
The sequence:
the associated graded of the filtered object abelian category
A.
If
A
G*A=
(GpA)pE~
(A,F*A)
is
in the
is an abelian category, then the
class of all filtered objects in
A,
together with all maps of
filtered objects, forms an additive (but, except in trivial cases, not abelian) category, and the assignment: is a functor from the additive category of all filtered objects 235
236
Section 6
in A
A
into the abelian category
and maps of degree
Definition 2. gory
Let
A
A?
of
?-graded objects in
O. be a filtered object in the abelian cate-
A. i)
The filtered object
only if there is an integer ii)
only if iv)
A If
F (A) = O. P is said to be codiscrete if and
A a
The filtered object
is said to be discrete if and such that
b
The filtered object
only i f there is an integer iii)
A
such that A
Fa (A) = A.
is said to be finite if and
is both discrete and codiscrete. A
is a filtered object, then for each integer
p,
we have the natural mapping:
Therefore, the sequence: dexed by the integers.
(A/FpA)pE? is an inverse system inIf the object
A,
together with the
natural mappings:
A-+A/F A, is an inverse limit of Pc? , P this inverse system, then we say that the filtered object (A,F*A) v) A,
is complete. If
A
is a filtered object in the abelian category
then for each integer
p
we have the natural inclusion:
Therefore the sequence: system indexed by the integers. with the natural inclusions:
F
is a direct
If the object
-p
A
-+
A,
A,
all integers
together p,
is a
direct limit of this direct system, then we say that the filtered object vi)
(A,F*A)
is co-complete.
The filtered object
A
is Hausdorff if and only if
the infimum of the decreasing sequence of subobjects
FpA,
Filtered Objects p E 1',
of
vii)
is zero:
A,
n F A:o pE1' P
The filtered objects
237
o.
A
is cO-Hausdorff if and only
if the supremum of the increasing sequence of subobjects of F
-p
A,
pG1',
is
A,
A:
I F A:o A. pE;r -p Remark
1.
A be an abelian category and let
Let
A:o (A, (F pAl pE1')
A.
be a filtered object in the abelian category
Then we have the induced filtered object
AO,
in the dual category ject.
o
A
:0
-p
A) E ), P l'
which we call the dual filtered ob-
Then the dual of the dual of
A,
Oo A ,
is of course
The reader will verify that, the filtered object
A is discrete (resp.:
abelian category
(A, (A/F
A
A.
in the
co-discrete, finite,
complete, co-complete, Hausdorff, cO-Hausdorff) iff the dual O A
filtered object
in
AO
is co-discrete (resp.:
discrete,
finite, co-complete, complete, co-Hausdorff, Hausdorff).
Thus,
the concepts of "discrete" and "co-discrete" are dual to each other, and similarly for "complete" and "co-complete", and for "Hausdorff" and "co-Hausdorff"; while the property of being "finite" is self-dual. Remark
2.
Let
A be an abelian category.
Then the filtered
objects that we have defined are sometimes called filtered objects with decreasing filtration in the abelian category
A.
One can define a filtered object with increasing filtration in the abelian category A
isan object in
p E 1',
such that
tiona I convention:
A,
A to be: and
FPA
FPAC FP+lA,
a pair
P (A, (F A)PE1')'
is a subobject of all
all
p E 1'. p E 1',
A,
where for all
If we make the notathen every filtered
Section 6
238
A
object with increasing filtration in the abelian category
becomes a filtered object with decreasing filtration, and vice versa.
We define a map of filtered objects with increasing
filtration in the abelian category
A to be a map of the cor-
responding filtered objects with decreasing filtration in the abelian category
A;
and we call a filtered object with in-
creasing filtration discrete, co-discrete, finite, complete, cocOHlplete, Hausdorff, or, respectively, co-Hausdorff, iff the corresponding filtered object with decreasing filtration is discrete, co-discrete, finite, complete, co-complete, Hausdorff, or, respectively, co-Hausdorff. Remark 3.
If the abelian category
A is such that denumerable
direct sums of objects exist, and is also such that denumerable direct limit is an exact functor, then it is easy to see that a filtered object
(A,F*A)
in the abelian category
co-Hausdorff iff it is co-complete.
A is
(E.g., this is the case if
A is the category of abelian groups). Remark 4.
A is
In the special case that the abelian category
the category of abelian groups, we can put a natural topology on
A
such that
Namely, we give
A A
becomes a topological abelian group. the topology, such that a complete system
of neighborhoods of zero is
{F pA: p E 'l! } •
see that, the filtered abelian group spectively:
Hausdorff; respectively:
Then, it is easy to
(A,F*A)
is complete (re-
discrete) in the sense
of Definition 2 above iff the topological abelian group complete as uniform space (respectively: cal space; respectively: Definition 3.
Let
A
is
Hausdorff as topologi-
discrete as topological space).
(A,F*A)
be a filtered object in the abelian
Filtered Objects category f:B -+ A
A.
B
If
integers
tration on the object
B
of filtered objects"). of the filtration of A,
then there is induced a F B = f- l (F A), p p
such that the map
P
=
(F A)
P
B
As a special case, if
n B,
all
duced filtration from
p
all integers
I
B,
f
is a subA,
which we
such that
is a filtered object
(A,F*A)
A, then for every integer
is a subobject of
F
is a map
p (: J'.
in the abelian category FpA
B
inherits a filtration from
As further special case, if
that
all
We will call this the pre-image under A.
then
f:B-+A
call the induced filtration on the subobject F B
and i f
(This can be described as, "the coarsest fil-
p E J' .
object of
A,
namely the one such that
B,
A,
is any object in the category
is any map in the category
filtration on
239
A.
A,
p
we have
and therefore we have the in-
Explicitly, the p' 'th filtered piece
if
p' ':'p,
if
p' ':::'p,
of
(F A)
p
p'.
We have also another similar construction. Namely, if is a filtered object in the abelian category B
is an object in
A
and if
is induced a filtration on tegers B
p.
f:A+B
B,
is a map in
such that
A,
if
A, then there
FpB=f(FpA),
all in-
(This can be described as, "the finest filtration on
such that the map
f:A-+B
We call this the image under special case, if
B
is a map of filtered objects"). f
of -the -
filtration of
is a quotient-object of
herits a filtration from
A,
tion on the guotient-object
A,
then
A. B
As a in-
which we call the induced filtraB.
Section 6
240
As a further special case, if
A,
ject in the abelian category have the quotient-object
(A,F*A)
then for every integer
A/FpA
of the object
fore we have the induced filtration from p' 'th filtered piece
all integers
p'.
Remark:
(A,F*A)
Let
A,
gory
and let
of
Fpl (A/FpAl if
p' ':'p,
if
p'
is a filtered ob-
A.
A,
p
we
and there-
Explicitly, the
A/F p A
is
~p,
be a filtered object in the abelian cate-
{(B,R)}
be a subquotient of the object
A.
Then there are two obvious ways to induce a filtration on the object
B.
First, if we write
B=A'/A",
are uniquely determined subobjects of A'
has the induced filtration from
subobject of tion from
A,
A'
and then
A A
B=A'/A"
A/A"
A/A".
two filtrations on
then
by virtue of being a
A'.
A;
A/A"
and therefore
But A
B = A I /A"
by virtue of being a sub-
B
coincide.
Therefore, whenever {(B,R)}
subquotient of the filtered object A,
A,
then
B
inherits
which we call the induced filtra-
(Explicitly, if one fixes an exact imbedding from some
full exact abelian subcategory
A'
of
A that is a set into
the category of abelian groups, such that all
pE&"
by
We leave it as an exercise to prove that these
a natural filtration from
FpA,
A" c A',
A"
has the induced filtration from
has the induced filtration from
tion.
and
has the induced filtra-
virtue of being a quotient-object of
is a
with
A'
by virtue of being a quotient-object of
on the other hand,
object of
where
B, and
A'
and
A",
A'
where
contains
A,
{(B,R)}=A'/A",
Filtered Objects then
F B= {a' +A":a' EA', p
Lemma 1.
a' EF A}, p
filtered object in the abelian category of
A.
Regard
duced filtration from integer (B,F*B)
all integers
A be an abelian category.
Let
subobject
241
B
A,
(A,F*A)
and let
be a
B
be a
as a filtered object with the in-
(A,F*A).
Suppose that there exists an
AcB. Then the filtered object Po is complete iff the filtered object (A,F*A) is com-
Po
such that
Let
pE;:r).
F
plete. Proof:
Case 1.
A is closed
Suppose that the abelian category
under denumerable direct products of objects.
Then, notice that,
since denumerable direct products of objects exist in the abelian category
A,
we have that inverse limits over denumer-
able directed sets exist in we have that F pB = (F pAl
n B = F pA.
A.
For each integer
p
such that
F Ac F AC B, and therefore that P Po Therefore, we have the short exact se-
quence:
Passing to the inverse limit for
P'::' Po
(as
p .... + 00),
we have
the exact sequence:
.... -A
(1)
B
Therefore, we have the commutative diagram with exact rows: (2)
0---':1 o
--.;>
B
0 :1 :r--:> A
ljm [F 13]--:> lim [F A]--:> AlB P'::'PO P P'::'PO P
242
Section 6
Diagram chasing in this commutative diagram, we see that the map
P
is an epimorphism.
Therefore the sequence (1) is a
short exact sequence.
phism, and
(B,F*B)
B
is complete iff
By definition (A,F*A)
is complete iff
a
is an isomor-
is an isomorphism.
from the commutative diagram (2) and the Five Lemma, B
isomorphism iff
a
But
is an
is an isomorphism, completing the proof of
Case 1. Case 2.
Then notice that, for every fixed object tor
A is arbitrary.
Suppose that the abelian category
G = Hom (C, ) A C
C
A,
in
the func-
is a left-exact functor, and is also a func-
tor that preserves arbitrary inverse limits indexed by directed sets, whenever they exist.
(In fact, this functor even preserves
arbitrary inverse limits indexed by set-theoretically legitimate categories, whenever they exist.) (GC(A),GC(Fp(A))pE~)
we have that
Since
G C
is left exact,
is a filtered object in the
category of abelian groups; denote this filtered abelian group by
G (A).
c
And
G (B) C
that the functors (1)
If
0
G
c
is a
subgroup of
GC(A).
have the following property:
isadirectedset,if
(X.,a .. ). 1.
the object
X
ai:X->-X
i
A
X
is an
are maps in the category
A,
then
together with the maps
iff for every object
together with verse system groups.
G (ai)' C
is an inverse if
verse limit of the inverse system gory
'ED
1.J 1., J
system of objects and maps in the category object, and if
Notice also,
i E 0,
C
A,
ai'
(X. ,a .. ). 1.
in
i ED,
are an in-
'ED
in the cate-
1.J 1.,J
A,
we have that
GC(X)
are an inverse limit of the in-
(GC(Xi),GC(aij))i,jED
in the category of abelian
(Of course, this property generalizes, beyond existence
Filtered Objects
243
of inverse limits of inverse systems indexed by directed sets, to existence of inverse limits of functors defined on categories that are sets).
From property (1) above, it follows that, the
filtered object
A
(resp.:
B)
complete, iff for every object group
(resp.:
GC(A)
abelian groups.
GC(B»
in the abelian category C
in
A,
A
is
the filtered abelian
is complete in the category of
Therefore, to prove the theorem in general, it
suffices to prove it in the case that the abelian category is the category of abelian groups.
A
And Case 1 covers that
case.
Q.E.D.
Remark:
Let
A
be the category of abelian groups and let
be a filtered object in
A.
If
B
A
is any subobject (i.e., sub-
group) of
A,
then in Lemma 1 above we have considered the con-
dition on
B,
that "there exists an integer
B::J F A". p
In terms of the topology on
A,
p
such that
introduced in Remark
4 following Definition 2, this condition is equivalent to, is open in
"B
A."
Definition 4.
Let
A
be an abelian category, and let
a filtered object in the abelian category exists in the abelian category the completion of
A,
A,
A.
If
A
be
lim A/F A
p",++oo
p
then this object is called
and is denoted
1\
A.
If
lim F p->-+oo
A -p
exists, then this object is called the co-completion of
A,
and
is denoted co-comp(A). Of course, from Definition 4 above, it follows immediately that, if denumerable direct products (resp.: ect sums) exist in the abelian category filtered object A
(resp.:
A
in
A,
A,
denumerable dirthen for every
we have that the completion
the co-completion co-comp(A)
of
A)
exists.
1\
A
of
Section 6
244
Also, from Definition 2, course follows that, if
A
(iv), and Definition 4, it of
is an abelian category, and if
is a filtered object in the abelian category complete iff both (i) A
A -+ A
Clearly, if
category
A
A
is
A.
is a filtered object in the abelian
then a completion of
A,
then
exists, and (ii) the natural mapping:
is an isomorphism in the abelian category
Remark 1.
A
AA
A,
A
in the abelian category O
exists iff a co-completion of the dual filtered object
in the dual abelian category incide.
A
O
A
A
exists, in which case they co-
Passing to the dual categories, it follows that a co-
completion of
A
in
A
O
exists iff a completion of
A
in
O
A
exists, in which case they are the same. Corollary 1.1.
Let
A
be an abelian category such that de-
numerable direct products of objects exist. tered object in B
A,
and let
B
Let
be a subobject of
A
be a fi1A.
Regard
as being a filtered object with the filtration induced from
A.
Suppose that there exists an integer
p
such that
F AC B. P
Then
and
1)
The natural map:
BI\ -+ AI\
2)
The natural map:
A-+AA
is a monomorphism, induces an isomorphism:
AI\ IBI\ "" AlB. Proof:
By the proof of Case 1 of Lemma 1, we have the short
exact sequence 1)
0
-+
BI\ -+ AI\
-+ AlB -+
0,
(equation (1) in the proof of Case 1 of Lemma 1). lent to the conclusions of the Corollary. Remark 2.
A slight refinement of Corollary 1.1 is
This is equiva-
Filtered Objects Corollary 1.1.1.
245
A be an abelian category such that de-
Let
numerable direct products of objects exist. tered object in
A,
let the subobject A,
and let B
of
A,
B
Let
A
be any subobject of
and the quotient object
be a filA.
Then
A/B
of
both be regarded as filtered objects with the filtrations
induced from
A.
Then the induced map:
B/\
-+-
A/\
is a monomor-
phism, and there is induced a natural monomorphism:
in the category
A.
If the abelian category
A
is such that
denumerable direct product is an exact functor, then the natural monomorphism (l) is an isomorphism. Since
Proof:
F B = (F A)
P
p
n B,
we have the short exact sequence
0'" (B/F B) ... (A/F A) ... {A/ (B + F A)) ... 0, p p p But
F (A/B) = (B + F A) /B.
P
Therefore
P
all integers
p.
A/ (B + F A) "" (A/B) / (F (A/B)).
P
P
Therefore, the above short exact sequence can be rewritten as the short exact sequence: 2)
0'" (B/F B) ... (A/F A) ... (A/B) / (F (A/B)) ... 0, p p p
all integers
p.
Passing to the inverse limit as
p ... + 00,
we
obtain the exact sequence 3)
/\
O"'B"'A
/\p
/\
-+(A/B) ,
which proves the first part of the Corollary.
If the functor,
denumerable direct product, is exact in the abelian category A,
then throwing the sequences (2) through the exact connected
sequence of functors (in fact, sequence of derived functors)
246
Section 6 l [lim (B/F B) 1 = 0,
and noting that
p:-+oo
B
constant inv. system we deduce that the map
by an epimorphism,
maps into (B/F B) E p
p
since the
p p 'Z'
in the sequence (3) is an epimorphism.
This proves the Corollary. corollary 1.2.
Let
A
be an abelian category such that denum-
erable direct products of objects exist.
A.
object in the abelian category The natural mapping:
1)
for all integers 2)
Let
A
be a filtered
Then
A
is an epimorphism,
A ->- (A/FpA)
p.
The kernel of the mapping in (1) is
pletion of
where the subobject
F A
P
of
A
is regarded
as a filtered object with the filtration induced from 3)
For all integers
p,
the natural mapping:
A. A->-AA
induces an isomorphism,
Proof: 1.1.
Let
Then
B
obeys the hypotheses of Corollary
The conclusions of Corollary 1.1 then imply the conclu-
sions of Corollary 1.2. Remark 4.
Let
A be any abelian category such that denumerable
direct products of objects exist, and such that the direct limit over the directed set of non-negative integers is an exact functor.
Then a filtered object in the abelian category
complete iff it is cO-Hausdorff. object in
A.
Then
A
(Proof:
is co-Hausdorff iff
Let
A
A
is co-
be a filtered
l F A = A, pEiI' P
and
A
is co-complete iff A,
lim F A = A. Since, in our abelian category pciI' -p we have that denumerable direct limit is an exact functor,
it follows that for any increasing sequence of sub-objects, the
Filtered Objects
247
direct limit is the supremum as subobjects.
I F A = lim F A, pEil -p pE;p: -p F -p A
of
A,
In particular,
for the increasing sequence of subobjects
p Eil).
It follows readily that, if
a filtered object in such an abelian category completion of the filtered object
I F A pEil -p
subobject
of
A
A
A,
(A,F* (A)
is
then the co-
exists, and is simply the
with the filtration induced from
A.
Of course, the category of abelian groups obeys the hypotheses of this Remark. Lemma 2. A.
Let
teger A/\
Let B
A
be a filtered object in the abelian category
be a subobject of such that
A,
such that there exists an in-
A) C B. Suppose that the completion Po exists in the abelian category A. Regard B as
PO
of
Let us now return to the general situation.
A
(F
being filtered object with the induced filtration from Then the completion A,
where
Note:
B
B/\
of
B
A.
exists in the abelian category
is given its induced filtration from
A.
Actually, under the hypoth2ses of Lemma 2, a bit more can
be said.
Namely, one
exists in
A
CiiTI
show that the completion
iff the completion
B/\
of
B
A/\
of
A
exists in
A.
We
will not make any use of this stronger observation, and we do not include a proof of this stronger observation. Proof: l~m
We know that
B/FpB
lim A/F A pEil p
exists; we must show that
exists.
pEil For
p
~
PO'
we have
short exact sequence: (1)
F B = FA. P p
Therefore we have the
248 Let
Section 6
8: [l)m
A
A B
+-
F A
F':'PO
P
be the map induced by the Then for every
Pl':'PO'
and let
8 , P
K = Ker 8.
we have the commutative digram with
exact rO'ils: --> A
B
[I
8
Pl
--.....:::..>
from which we deduce a mapping
A B
K+ (B/F
B),
all integers
Pl I claim that (2)
The object
K,
together with the maps
for
are an inverse limit of the inverse system in the category
(B/F
Pl ':'P O' Pl
B)
>P
Pl- 0
A.
In fact, as in the proof of Case 2 of Lemma 1, to prove this, it is necessary and sufficient to show that, for every object in
A,
that the abelian group
Hom (C,K) A
C
together with the
is an inverse for all ), Pl limit of the inverse system of abelian groups:
homomorphisms
HomA(C,a
Since the functor
Hom (C,) A
preserves
inverse limits over directed sets whenever they exist, and preserves kernels of maps, we are therefore reduced to proving assertion (2) in the case that groups.
A
is the category of abelian
But then, since inverse limit is a left exact functor,
passing to the inverse limit for tain the exact sequence
P':'PO
in equation (1), we ob-
Filtered Objects
249
(3)
B
Exactness of the sequence (3) implies that
K = lim F B'
therep Therefore assertion (2) is true for p~'po
by proving assertion (2).
the category of abelian groups, and therefore, for an arbitrary
A.
abelian category in
And in particular,
lim (B/FpB) p~'po
A.
Corollary 2.1.
Q.E.D.
Under the hypotheses of Lemma 2, we have that
(1)
The natural map:
B/\->-A/\
(2)
The natural map:
A->-A/\
Proof:
exists
is a monomorphism, and induces an isomorphism:
In the course of proving Lemma 2, we have established
an exact sequence:
The composi te:
A ->- A/\
~
A/B
therefore an epimorphism.
is the natural mapping, and is Therefore
is an epimorphism.
p
Therefore we have the short exact sequence (1)
/\
/\
o ->- B ->- A +(A/B) ->- O.
This short exact sequence is equivalent to the conclusions of the corollary. Corollary 2.2.
Let
a filtered object in
A A
be an abelian category, and let such that the completion
A/\
A of
be A
exists. Then (1)
The natural mapping:
for all integers
p.
/\
A ->- (A/F A) p
is an epimorphism,
Section 6
250
regarded
F A,
the subobject
p,
For every integer
(2)
P
as filtered object with the induced filtration from such that the completion, tion, the completion
(FpA)A
(F A)A
of
P
P
is
In addi-
exists.
of F A
A,
is naturally isomorphic
to the kernel of the mapping (1). For all integers
(3)
p,
the natural mapping:
A -+ AA
in-
duces an isomorphism
AI FA"':. AAI p
Proof: 2.1.
Let
B = F A. p
(F A) A .
P
Then
B
obeys the hypotheses of Corollary
The conclusions of Corollary 2.1 then
imply the conclu-
sions of Corollary 2.2.
Q.E.D.
Notice that Corollaries 2.1 and 2.2 above are direct generalizations of Corollaries 1.1 and 1.2 respectively. Lemma 3.
A.
Let
A
be a filtered object in the abelian category
If the filtered object
Corollary 3.1. category
A.
Let
A
A
is complete then
A
be a filtered object in the abelian
If the completion
AA
of
A
exists, then the in-
fimum of the decreasing sequence of subobjects of p E ~,
exists.
n pEJ"
is Hausdorff.
A:
FpA,
And then
(F A) = Ker(A -+AA). p
Proofs of Lemma 3 and of Corollary 3.1:
If
C
is a subobject
A AA=lim(A/F A), the composite: C-+A+A pE~ p is zero iff the composites: C-+A+(A/FA) are zero, all inte-p gers p, iff C C F A, all integers p. It follows that
of
A,
then, since
p
is an infimum of the subobjects
F A
P
of
A, P E Z.
Filtered Objects
251
n F A exists, and Ker (A -+ AI\) = n F A, proving pE~ p pE~ P Corollary 3.1. By Definition 2, part (iv), and Definition 4, Therefore
we have that
A
is complete iff
is an isomorphism.
Therefore, if
AI\ A
exists and the map
is complete, by Corollary
n F A =Ker(A -+AI\) = 0, pEZ' p
3.1 we have that
A -+ AI\
and
A
is Hausdorff. Q.E.D.
Corollary 3.2.
Let
Then
A
be an abelian category, and let
A such that the completion
filtered object in ists.
A
AI\
of
is Hausdorff iff the natural mapping:
A
be a
A
ex-
A -+ AI\
is a monomorphism. Proof:
By Corollary 3.1,
n
Hausdorff iff
F A=
pE;r. p
°
n F A = Ker (A -+ AI\). There fore pEZ' p iff A -+ AI\ is a monomorphism.
is
A
Q.E.D. Definition 5.
Let
A be an abelian category, and let
filtered object in the abelian category AI\
completion
of
A
A.
of
A
duced filtration from
/\
A,
completion,
(FpA)I\, A/\,
if we regard the
(F A)I\ of F A P P We define a filtration on
then the completion AI\ .
by defining the p'th filtered piece
the subobject
p,
Then,
as being a filtered object with the in-
exists, and is a subobject of A ,
be a
Suppose that the
as defined in Definition 4 exists.
by Corollary 2.2 above, for every integer subobject
A
all integers
p.
of any filtered object
ists, in the arbitrary abelian category
Fp(A/\)
of
AI\
to be
We thereby regard the A,
A,
whenever
AI\
ex-
as being a filtered
object. Thus, if category
A,
A
is an arbitrary filtered object in any abelian
and is such that the completion
AI\
of
A
exists,
Section 6
252 then
AA,
by Definition 5 above, is itself naturally regarded
as being a filtered object, and explicitly the p'th filtered piece
is
of
p.
for all integers Proposition 4.
A.
gory
Let
A
be a filtered object in an abelian cate-
Suppose that the completion
(1)
AA
(2)
We have a natural mapping
AA
of
A
exists.
Then
is complete as filtered object. l:A ... AA
of filtered
objects.
(3)
A (A , l)
The pair
is universal with these properties.
Proof:
By Corollary 2.2, we have that
A/FpA.
Therefore
Definition 1,
P
P
lim AA/F (AA) '" lim A/F A=AA, so that by PE~ p pE~ P (iv), the filtered object AA is complete. (F A)A, F A into P P and is therefore a map of filtered objects.
l:A .... AA
The natural map all integers
AA/F (AA) =AA/(F A)A",
p,
clearly maps
It remains to prove universality. In fact, gory
A
let
B
be a filtered object in the abelian cate-
that is complete, and let
objects.
we deduce a map,
quotients.
Since
B
such that
B00
0
B : A/F A .... B/F B p p p
is a map
B :AA .... B. 00
l = B.
For every integer
by pass ing to the
is complete, we have that
Therefore the inverse limit of the maps
p,
be a map of filtered
We must show that there exists a unique map of fil-
tered objects B00 :AA .... B p,
B:A .... B
Bp'
B = lim B/F B. pE~ p for all integers
From the commutative diagrams:
253
Filtered Objects B A
~B
1
A/F A P for all integers
p,
Bp
1
) B/F B, P
if we pass to the inverse limit for
p E 'J' ,
we deduce the commutative diagram: A
B
>B ------------~
lL
lid B
Boo
) A ------
which proves existence of Since
B
Boo.
It remains to prove uniqueness.
is complete, we have that
fore,to give a map in the category to giving maps:
A .... B/F B
whenever
the digram:
q.:::. p,
p
B,
A,
B = lim B/F pB.
ph
8:A ->- B,
for all integers
p,
There-
is equivalent such that,
A~l p
is
commutative:
The map
will be a map of filtered integers to
0,
8: A ->- B
in the abelian category
objects iff
p; equivalently, iff the maps: all integers
p.
whenever
A) cF
p
A ->- B/F pB
for all
(B),
F A inP 8:A->-B of
map
A is equivalent to such that,
8 p.•
q.:::. p,
p
Therefore, to give a map
filtered objects in the abelian category giving maps
8(F
A
the diagram:
254
Section 6 8
AT
0
A/FpA
is
commutative.
replacing
'BT
q
p
;>B/F B P
Applying these same considerations, with
A, we see similarly that, to give a map
filtered objects in the abelian category giving maps
P : A/\ /F (A/\) -+ B/F B p p p
that, whenever
q
~
P9,
1
is equivalent to
for all integers
p,
of filtered objects
f
) B/F pB
~
8
/\
A
A/F A'::;. A /F (A ). p
from
A
into
B
A-+AA
Therefore, the maps
p
are in one-to-one
correspondence with the maps of filtered objects the correspondence being given by
8=
p
from
pOl.
proves the uniqueness part of universality. Corollary 4.1.
such
But, by Corollary 2.2, the natural map:
induces an isomorphism:
B,
of
»B/F B
Pp
A/\/F (A/\) P
into
-+ B
p, the diagram:
A/\/F (A/\) q
is commutative.
A,
p :A/\
AA
A/\
This Q.E.D.
The hypotheses being as in Proposition 4, we
have that the map induced by the natural map,
l:A -+A/\,
on the
p'th graded pieces is an isomorphism
for all integers Proof:
p.
For every integer
with exact rows:
p,
we have the commutative diagram
Filtered Objects
By Corollary 2.2, the maps fore, by the Five Lemma, Theorem 5.
Let
A
G (l)
p
yare isomorphisms.
is an isomorphism.
be an abelian category, let
A
A,
fil tered obj ects in pose that
Sand
255
and let
f: A .... B
Q.E.D.
A
and
B
A.
be a map in
is complete and co-Hausdorff, and that
complete and Hausdorff.
There-
B
be Sup-
is co-
Then the following two conditions are
equivalent. (1)
f
is an isomorphism of filtered objects.
is an isomorphism from restriction of
A from
F A p
(2)
p
(f):
Proof:
p
(A) ....
in the category
A,
for all integers
G
p
p, (B)
d~l,
and the
p) .
is an isomorphism of graded objects.
Clearly,
the integer
B
f
is an isomorphism in the category
F B, p
onto
G* (f)
G
onto
to
f
for each integer G
A
(I.e.,
the map in the category
(I.e.
I
A,
is an isomorphism.)
(1)==> (2).
Assume (2).
Then by induction on
I claim that, for every integer
that the map induced by
p,
we have
f:
(1)
is an isomorphism. In fact, for
d = 1,
equation (1) says that
isomorphism, which is condition (2). tion is established for the integer
If d,
d"::'l,
G (f)
p
is an
and the asser-
then we have the commu-
Section 6
256
tative diagram with exact-r0WS:
for each integer isomorphism.
p.
By the inductive assumption,
By the case
fore by the Five Lemma,
d = 1,
B
a
tration from (2)
A.
F A=
P
FpA
(3)
and each
A
is complete,
is complete for the induced fil-
Therefore
lim (FpA/FplA). p'~p
Considering equation (1), it follows that
l~m
(F B/F
I
B)
p' >p p P But then by Definition 4 applied to the filtered ob-
FpB,
object
p,
d > 1.
by Lemma 1 we have that
ject
There-
is an isomorphism, completing the
Since by hypothesis the filtered object
exists.
is an
is an isomorphism.
inductive proof of equation (1), for all integers integer
y
we have that the completion
F B P
(F B)A p
of the filtered
exists, and that
(F B)A P
=
lim
pl+-~p
(F B/F ,B). p P
Passing to the inverse limit of the isomorphisms (1) in the category
A, we obtain an isomorphism
(4)
in the category
A,
commutative diagram:
all integers
p.
But then we have the
Filtered Objects
257
(F A) 1\ _ ... ____ 2'_____ .____ ._> (F B) 1\
(5)
~l
/1'
F A
) F B
P
in the category phism.
A.
P
Since
F A
is complete,
p
is an isomor-
Therefore, from the commutative diagram (5), it follows
that the natural map:
F p B'" (F p B)
1\
is an epimorphism.
That is,
we have that the natural map: (6)
F B ... [lim (F B/F ,B»)
p' ~p
p
is an epimorphism.
p
p
Since inverse limit preserves kernels, the
n F ,B. p' >p p thesis Hausdorff, we have-that
kernel of this map is
the map (6) is an isomorphism. the commutative diagram (5).
FA'" F B
P
p
tegers
n F ,B
p'~p p
and
B
is by hypo-
is zero.
Therefore j
in
Therefore, from the diagram (5), f
is an isomorphism in the category
A,
all in-
p.
Next, consider the filtered objects A
B
But this map is the map
we have that the map induced by (7)
But, since
in the dual category
filtered piece of
AO,
resp.:
AO. BO,
AO
and
BO
Explicitly, the
p'th
is the quotient object
respectively of resp. : B/F -p B, of A, A, -p category A. Then the map of filtered objects in
B,
A/F
obeys the hypotheses of this Theorem.
dual to
in the
AO:
Therefore we have equa-
tion (7), which tells us that the map induced by
f
from the
258
Section 6 O
p'th filtered piece of
B
A,
A
or, translated back to
is an isomorphism in the category the category
O
into the p'th filtered piece of
that the map induced by
f
in the category
A: A/F
(8 )
-p
A -+ B/F
all integers
-p
B
is an isomorphism in the category
A,
for
p.
For any fixed integer exact rows:
p,
we have a commutative diagram with
y
o-_....
O---+)F B
p
By equation (7), A.
is an isomorphism in the abelian category
By equation (8) applied to the integer
A.
morphism in
Therefore by the Five Lemma,
morphism in the category all integers Remark 1.
A,
A
then define (A) = A/ (
-00
tion
AA
LF
pE;}' t:l
of
A
(resp.:
iff
G+ (A) = A)
Q.E.D.
n F A
pE;}' P
whenever it exists, and
whenever it exists.
(E. g,
exists, then by Corollary 3.1
exists).
Thus,
co-Hausdorff)
G _00 (A)
is an iso-
This fact, and equation (7) for
Dually, if the co-completion co-comp(A) of G_oo(A)
f
is an iso-
is a filtered object in the abelian category
00
G
A.
E
implies condition (1).
p,
If
-p,
the filtered object iff
G+oo(A)
exists and is zero).
tered objects, and if the induced map in
A,
G+oo(A)
and
A A
if the compleG+oo(A)
exists.
exists, then is Hausdorff
exists and is zero (resp.: If
f:A -+ B
G+oo(B)
is a map of fil-
exist, then we have
G+oo(f): G+oo(A) -+G+oo(B),
by restriction.
Filtered Objects Similarly, i f
Remark 2.
and
G_00 (A)
G_00 (B)
259
exist, then we have
The proof of Theorem 5, also provffithe following
somewhat stronger result: Corollary 5.1. B
A
Let
be an abelian category, and let
A,
be filtered objects in
G_oo(A),
G_oo(B)
exist.
such that
G+oo(A),
and that the filtered object: tration induced from
and
G+oo(B),
Suppose also that the filtered object
(with the filtration induced from
A/G+ oo (A)
A
B)
Ker(B
+
A)
is complete,
G_00 (B))
is co-complete.
If
(with the filf:A
+
B
is any
map of filtered objects, then the following two conditions are equivalent: (1)
f
is an isomorphism of filtered objects,
(2)
Gp(f)
is an isomorphism in the category
(The inequality on for
p = +00
and
p
meaning, "for all integers
A,
p,
and also
-00" ) .
The proof is very similar to that of Theorem 5. Remark 3.
Suppose that we have the hypotheses of Theorem 5,
and that condition (2) of Theorem 5 holds.
Then by Theorem 5,
we also have that condition (1) of Theorem 5 holds. it follows, in this case, that
A,
and also
B,
Therefore
are both com-
plete and co-complete. Remark 4.
Similarly, if the hypotheses of Corollary 5.1 hold,
and if condition (2) of Corollary 5.1 holds, then it follows that, if
K = Ker (A
and co-complete. Remark 5.
+
G A), -00
And that
is both complete B
also has this property.
Corollary 5.1, as has been indicated, can be proved
Section 6
260
directly.
However, it can also be deduced as a corollary of
Theorem 5. Sketch of Proof:
Let
K = Ker (A .... B_ooA),
K=Ker(B .... G_ooB),
B' =B/B/G+ooB.
A' = K/G+ oo (A) ,
Then if condition (2) of Corol-
lary 5.1 holds, one proves readily that condition (2) of Theorem 5 holds for the map of filtered objects induced by f,A' -7B'.
But
A'
is comPlete and co-Hausdorff, and
co-complete and Hausdorff. A' +B'
induced by
f
B'
is
Therefore by Theorem 5 the map:
is an isomorphism of filtered objects.
One then deduces readily, from two applications of the Five Lemma, since the map
G+oo(f)
f:A + B
and
G_oo(f)
are also isomorphisms, that
is an isomorphism of filtered objects.
Let us now state the dual of Corollary 2.2. Corollary 2.2°. category ists.
A.
Let
A
be a filtered object in an abelian
Suppose that the co-completion, co-comp(A),
Then for every integer of
p,
if we regard the quotient-
as being a filtered object with the fil-
A
tration induced from
A,
then exists,
(1)
co-comp(A/FpA)
(2 )
the natural map:
co-comp (A) -7 co-comp (A/F A) P is an epimorphism, and
(3)
the kernel of the epimorphism in (2) is naturally isomorphic to
Proof:
ex-
Corollary 2.2°
FpA,
all integers
p.
immediately follows from Corollary 2.2
by passing to the dual category. Before stating the next theorem, we note that, dual to Definition 5, if gory
A,
A
is a filtered object in the abelian cate-
such that co-comp(A)
exists, then we define a filtra-
Filtered Objects tion on co-comp(A)
by defining
of the natural mapping integers
F (co-camp A)
to be the kernel
p
¢p: co-comp(A) +co-comp(A/FpA),
(By Corollary 2.2°,
p.
261
all
conclusion (1), co-comp(A/F A) p
exists; and by Corollary 2,2°, conclusion (2), the mapping is an epimorphism, all integers object in the abelian category and if
AO ,
O
A
p.)
Then, if
A
¢p
is a filtered
A such that co-comp(A)
exists,
is the dual filtered object in the dual category
then the dual filtered object: O
is the completion of
A
co-comp(A)o
in the dual category
of co-comp(A)
AO .
So that,
if we prove any theorem about completions (or, respectively, co-completions) regarded as filtered objects, then we automatically have established the truth of the dual theorem, a theorem about co-completions (or, respectively, completions). Remark:
Notice that, by the definition above of the filtration
on co-comp(A)
(that
Fp (co-comp A) = Ker (co-comp (A) +
co-comp(A/FpA»,
and by conclusion (3) of Corollary 2.2°, it
follows that, if
A
gory
A
is any filtered object in an abelian cate-
such that co-comp(A)
co-comp A + A
exists, then the natural map:
induces isomorphisms,
F (co-comp A) ':; F (A), p p Theorem 6.
Let
A
filtered object in and (co-comp A)A category
A
all integers
p.
be an abelian category, and let A,
such that
AA,
A
co-comp (A ),
A
be a
co-comp(A)
exist (e.g., it suffices that the abelian
be closed under denumerable direct products and
denumerable direct sums of objects).
Then there is induced a
canonical isomorphism of filtered objects
262
Section 6
Proof:
By Definition 5, we have that F (AA) =F (A)A, p p
all integers
p.
By Corollary 2.2, we have that the natural mapping:
A-+AA
in-
duces isomorphismS:
The dual of this last observation (see the
Remark just pre-
ceding this Theorem) is that, the natural mapping:
co-comp(Al-+A
induces isomorphisms: F (co-comp A) p
'! F p A,
all integers
p.
Therefore Fp(CO-COmp(AA»
(1)
(2)
and
Fp((co-comp A)A) = (Fp(co-comp A)lA", (Fp(A»A, gers
p.
tegers ( 3)
"'Fp(A/\) =(Fp(A»/\,
all inte-
Combining (1) and (2), we see that, for all inp,
we have the natural isomorphisms
F (co-comp (AA) ) '" F ((co-comp A)/\) "" (F (A»A. p p p By Proposition 4, conclusion(l), we have that the filtered
object
AA
is complete.
is co-complete.
The dual of this is that co-comp(A) A
Therefore, co-comp(A )
is co-complete.
is, the natural mapping is an isomorphism: co-comp (A) ~ l,;j,m F (co-comp (Al ) . p -p
(4)
The composite of the isomorphism (3) with the inclusion: F
A
-p
(co-comp (A » "" F
-p
((co-comp A)
/\
) c..... (co-comp A)
A
That
263
Filtered Objects is a map in the category p ++
A.
Passing to the direct limit as
and using equation (4), we obtain a natural map in the
00
category
A:
(5)
II B:co-comp(A )
By equation (3),
B
(co-comp A)
-+
1\
.
is a map of filtered objects.
The dual of equation (3), is that we have natural isomorphisms: 1\
1\
(co-comp(A ))/Fp(co-comp(A )) ~ II II (co-comp A) /F ((co-comp A) ) "" co-comp (A/F (A)),
(6 )
p
all integers Fix an integer B
PO
p
p.
(e. g., one can take
Po = 0).
Then the map
induces the commutative diagram with exact rows:
1
1
II II co-com (AI\) (co-comp(A ))---?co-comp(A ).....;.-p II ~ Po F ((co-comp (A )) a B Po II /\ , 1 \ ) , AJ (co-comp A) 0-;> F (( co-comp A) --»\ co-comp ~ 1\ ...... Q Po F ((co-comp A) ) Po O-F
yl
By equations (2) and (6) respectively, we have that the maps and
y
a
in the above diagram are isomorphisms. By the Five Lemma,
it follows that the map
B
is an isomorphism in the category
A. Finally, equation (2) the map
B
implies that, for all integers
II maps the p'th filtered piece of co-comp(A)
phically onto the p'th filtered piece of (co-comp A) that the map corollary 6.1.
B
1\
-
is an isomorphism of filtered objects.
p, isomor-
Le., Q.E.D.
The hypotheses being as in Theorem 6, for every
264
Section 6
integer
p
F (co-comp (AI\) ) "" F ((co-comp A)I\) "" F (AI\) "" (Fp (A) P P P
(1)
and
we have canonical isomorphisms )1\,
(co-comp(AI\))/F (co-comp(AI\)) ""
(2)
p
1\
(co-comp A) /Fp((co-comp A)
1\
) ""
co-comp (A ) /F p (co-comp A) "" co-comp (A/F p (A)). Proof:
Conclusion (1) of the Corollary follows from equations
(1) and (2) in the proof of Theorem 6.
Conclusion (2) of the
Corollary is the dual of conclusion (1).
(And also follows,
alternatively, from equation (6) in the proof of the Theorem and from conclusion (3) of Corollary 2.2 applied to the filtered object Remarks:
1.
co-comp(A)). From Theorem 6, it follows that if
tered object in an abelian category comp(AI\),
(co-comp A)
A,
and (co-comp A)I\
A
is a fil1\
A ,
such that
co-
all exist (this condi-
tion is automatic if, e.g., the abelian category
A
is closed
under denumerable direct products of objects and under denumerable direct sums of objects), then co-comp(AI\) and (co-comp A)I\ are both complete and co-complete (since by Theorem 6 they are isomorphic as filtered objects, and by Proposition 4, conclusion (1), the latter is complete, and by the dual of Proposition 4, conclusion (1), the former is co-complete.) 2.
Of course, from Corollary 4.1, and the dual of
Corollary 4.1, it follows that, if the abelian category
A
A
such that
AI\
is a filtered object in and
co-comp(AI\) exist,
then there are natural isomorphisms: 1\
G (co-comp (A )) "" G (A), p p
all integers
p.
Filtered Objects And, similarly, if co-comp(A)
265
and (co-comp A)A
exist, then
there are induced natural isomorphisms: G ((co-comp A) p
A
) '" G A, p
all integers
p.
We next prove a few general lemmas about inverse limits and
liml
Lemma
7.
over denumerable directed sets.
A
Let
be an abelian category such that denumerable
direct products exist and such that the functor "denumerable
AW into
direct product", from A
A,
is an exact functor.
be any complete filtered object in
Proof:
A.
Let
Then
First, notice that since denumerable direct products ex-
ist in the abelian category
A,
is exact, we have that
and
lim pE;r
and denumerable direct product liml
make sense on the cate-
pE;r
A indexed by the integers; and that
gory of inverse systems in
these form a cohomological exact connected sequence of functors, in fact, a system of derived functors, by taking the zero functor in dimensions
"I 0,1.
(See Intro., Chapter 1, section 7).
The short exact sequences:
o -+ F
A -+ A -+ Alp A -+ 0
P
for all integers
P
p
define a short exact sequence of inverse
systems in the category integers. functors
A,
indexed by the directed set of all
Throwing through the exact connected sequence of lim, liml, pE;r
pE;r
we obtain the exact sequence of six terms:
266
Section 6
(1)
dO 1 O->[lim F Al -+A ~ [lim (A/F A) l - [11m F A l P p p€:r p pE:r p
Ez.
[11ml A l - [lim pE:r pEp Since by hypothesis
A
l
(A/FpA) l--:> O.
Also, the inverse systems:
phism.
is an isomor-
is complete, the map and
(A)pEP
(A/F p A)pE:l7
are
quots. of constant inv. systems, so (Intro. Chap. 1, sec. 7, Thm. ' 1 have l ~m zero.
Substituting these facts into the exact se-
quence (1) implies conclusion of the Lemma. Remark.
The proof of Lemma 7 also shows that,
Corollary 7.1.
Let
A
be any filtered object, not necessarily
complete, in an abelian category theses of Lemma 7.
A,
where
A obeys the hypo-
Then we have an exact sequence of four
terms:
where
G+oo(A)
Remark:
is defined as in Remark 1 following Theorem 5.
In particular, it follows that, under the hypotheses
of Corollary 7.1, if [lj,m pE.;! A
l
F Al = 0 P
iff
A
is any filtered object in
A/G+ooA
is complete.
A,
then
Such a filtered object
may be called "complete but not Hausdorff".
Corollary 7.2.
The hypotheses being as in Corollary 7.1, if
is any filtered object in the abelian category
A,
then
complete iff
Remark:
Corollary 7.2 above is a converse of Lemma 7.
Lemma 7, Corollary 7.1 and Corollary 7.2 apply to an
A
A is
Filtered Objects
A,
abelian category
such that denumerable direct products ex-
ist, and such that the functor, from
W
A
"denumerable direct product"
A is an exact functor.
into
267
generalized, say, to abelian categories
Can these results be
A such that denumerable
direct products exist, whether or not denumerable direct product (An example of such an abelain category,
is an exact functor?
in which denumerable direct product is not exact, is the category of all sheaves of abelian groups on any topological space X
such that there exists a sequence of open subsets of
X
that the intersection is not open; see Example 3 below).
such
The
answer is "Yes", and we sketch the generalization in a series of exercises, most of the easy details left to the reader.
(No use
of these results will be made elsewhere in this book).
A be a category, let
Exercise 1.
Let
(*) and let
(Ai,aij)i,jED
direct system
(A, ,a, ,),
'ED
index
an object
A
iO ED,
ti:A .... Ai a
ij
0
for all
ti = t , j
for every
all
i ED
1.J
with
i,j ED with
and such that If
1.,J
iED
(Ai,aij)i,jED
be a directed class
be a direct system in the category
A indexed by the directed class 1.
D
D.
trivializes iff there exists an
A,
in
i2:.io;
such that
iO'::' i,
Then we say that the
and maps
TIi:A
such that iO'::'i '::'j;
there exists
JED
i
TIi
.... A, 0
ti = idA'
and such that, such that
o 'IT. ,
1.
is a direct system indexed by a directed
(*) A directed class D is a class ([K.G.l) together with a binary relatiorl"<" that is syrrunetric, transitive and such that x,y E D implies there exists zED such that x:5.z, y.::.z; and also such that D is non-empty.
268
Section 6
class
D
in a category
A
that trivializes as above, then it
is easy to see that
lim A. exists in the category A and is iED ~ canonically isomorphic to the object A. We sometimes say that the direct system trivializes to the object
A.
Also, if
is as above, then we sometimes say that the indicated i •
direct system trivializes past the index Exercise 2.
Let
A
and
S
be an additive functor from ject of where A.
A. B
Then let
MA
A
Define a pre-order in
Then (M A
M , A
A
into
S
and let
and
MA,
l:A .... B
f:B .... B'
in
A
F:A~>S
be an ob(l,B)
is a monomorphism in
by defining:
(l,B) '::'(l',B')
such that
f
0
1 = 1'.
together with this pre-order, is a directed class.
is a directed set iff the category
every
A
be the class of all pairs
is an object in
iff there exists a map
o
be abelian categories, let
A
is a set).
For
(1, B) E M ,
let B/A denote Coker (1). Then the assignA (l,B)Coker(F(B) .... F(B/A)) defines a direct system in
ment:
the abelian category
S
indexed by the directed class
We say that the satellite of
F
exists at
A
system trivializes in the sense of Exercise 1.
M . A iff this direct When this is
the case, by Exercise 1 the direct limit: lim
Coker (F (B) .... F (B/A) )
(1, B) EMA
exists in the category
S;
in fact, by Exercise 1, the direct
in the abelian cate(Coker(F(B) .... F(B/A))) (l,B)EM ' A S, indexed by the directed class MA even trivializes to
system: gory
an object of
S;
we denote this object by
it the satellite of ever
it exists.
F
(SF) (A),
evaluated at the object
A E A,
and call when-
Filtered Objects Exercise 3. F:A~>
8
Let
A
and
8
be abelian categories and let
be an additive functor.
category of
A
the satellite,
269
C denote the full sub-
Let
generated by those objects SF(A),
F
of
additive subcategory of
A,
exists at
A
in
A.
8,
such that
C
Then
and the assignment:
is an additive functor from
A
A~
is an (SF) (A)
C
into
A
has enough injectives (or even
which we denote by
SF. Example 1.
If the category
enough injective monomorphisms) then objects
A
in
A
8.)
Infact,if
from
(l,B)~MA
(l,B)
A
is
is a maximal element in the directed class
Therefore any direct system in any category indexed by the
directed class MA trivializes past the index the direct limit of any such direct (l,B).
(1
,B)
~
M ; A
and
system is the value at
Therefore
(1) where
F
is an injective monomorphism (*), then it is easy
to see that M . A
exists, for all
(and for all additive functors
into any abelian category such that
(SF) (A)
(SF) (A) = Coker (F (B) .... F (B/A» , (l,B)
is any element of
(or, weaker, such that
MA
such that
is injective
is an injective monomorphism).
Of course, if the abelian category
A
is such that
has enough injectives (or, weaker, is such that
(*) injective category such that always an
B
A
A
has enough
A monomorphism 1: A ... B in a category A is called an monomorphism iff whenever f: A .... C is any mono. in the A with domain A, then there exists a map g:C .... B g 0 f = 1. A monomorphism into an injective object is injective monomorphism.
Section 6
270
injective monomorphisms), then in SF
of
F
is defined.
[C.E.H.A.l
the right satellite
By our above observation, when
A is
such an abelian category (with enough injectives, or weaker, with enough injective monomorphisms), we have defined additive functor from above.
F
S,
an
as defined in Exercise 3
By equation (1) above, and by the definition in Chapter [C~l,
2, of
A into
SF,
we have that, whenever the right satellite (SF) of
exists in the sense of [C.E.H.A.l, then it exists in the
sense of Exercise 3 above and is defined on all of then these two definitions coincide.
A,
and
Therefore, the definition
in Exercise 3 above generalizes that of the right satellite as given in [C.E.H.A.l. Exercise 4. (*)
The hypotheses as in Exercise 3, let
f' f" 0-+ A I--~A -~A" -+ 0
abelian category
be a short exact sequence in the
A such that
is induced a natural mapping
S,
gory
(SF) (A')
0(*) :F(A") -+ (SF) (A')
which we call the coboundary.
0(*) 0 F(fll) = O.
Of course, if
exists.
V
Then there in the cate-
We have that
denotes the additive cate-
gory of all short exact sequences (*) in
A such that
in
is a natural trans-
C,
then the assignment:
(*)'V'v> 0 (*)
A'
is
formation of functors from the functor:
(*)'V'v> F(A") into the
functor:
AEC then (SF) (f') 00(*)=(
(*)'If'v> (SF) (A'). I f (*)EV with
Exercise 5. (*)
that F (T)
0
The hypotheses being as in Exercise 3, let
-.A'.....!.:.>A..f:~A" (SF) (A') ,
-+0
(SF) (A)
be a short exact sequence in and
(SF) (A")
A
exist. If the functor
is half exact, then the sequence: F(A') F(f')>>F(A)
F(fll»F(AII)~>(SF)
(SF) (A) (SF) (fll) ~ (SF) (A")
such
(A')
(SF) (f') >
Filtered Objects is exact in
B.
condition:
(If we weaken the hypotheses, by deleting the
"SF (A")
obtained from
271
exists",
then the sequence of five terms
by deleting the six'th term is exact; if we
(T)
further weaken the hypotheses, by deleting also the condition "SF (A) (T)
exists", then the sequence of four terms obtained from
by deleting the last two terms is exact).
Exercise 6.
Let
A
be an abelian category.
I(A) =A~
Then let
denote the category of all inverse systems in the category
A
indexed by all the integers, and all maps (of degree zero) of such inverse systems.
Then
pose that the category products exist.
means for
into
A = (A"
a, ,),
l
~~m l ~
lJ
A, 'E '
l, J
~
to exist.
(A)
1
left exact functor from
A
Sup-
is such that denumerable direct
I(A)
(S lim) iE~
use the notation:
is an abelian category.
Then the assignment:
is a functor from Given an object
A
I(A)
for
(A, ,a, ,), l
lJ
'E '\IU> lim A,
l,J ~
When
(S lim) into
l
by Example 1 we know what i t (S lim) iE~ (A) •
A
exists, we
(A)
Since
iE~
I(A)
iE~
and is a left exact functor.
~tm ~
is a
l
(and is therefore a
-
fortiori a half exact functor), by Exercise 5, whenever (*)
f' f" o +A'-A--!>A"
+ 0
is a short exact sequence in
I(A)
such that
liml A', iE~
and
t t l A"
all exist, then we have the exact sequence of six
terms in the abelian category
A:
Section 6
272 Example 2.
Let
A
be an abelian category such that denumerable
direct products of objects exist. category
A.
Let
A
be any object in the
Then, going back to the definition in Exercise
it is easy to see that the constant inverse system
I,
(A) iEJ' E I (A)
1 'ml exists at this constant inverse system, and JZ'l (In fact, i f A denotes the constant in fact that lim A = O. iEJ' (1, B) , then those elements of M , inverse system A in I (A) , A
is such that
such that
is an inverse system that is "constant past zero"-
B
i. e., such that the mappings for all integers (1, B) f MA
Coker
B) lEi! for any object
-T
-T
Bp
are identity mappings
p':: 0 - are confinal in
is such that
((~im
Bp+ 1
(~im
B
And, if
is constant past zero, then
B/A)) = 0.)
lEZ' A in
MA .
I(A)
The same argument shows that,
that is constant past zero, we have
that
liml A exists and is zero. Using this, it is also easy iEJ' to show that, if A is any filtered object in the abelian cate-
A,
gory
l' m1 F A 1 p pEZ'
then
lj,m pEJ'
l
always exists, and in fact
FA"" Coker (A P
-T
canonically, in the category of
A,
and where
A -T
i\
i\)
A,
where
AA
is the completion
denotes the natural map into the com-
pletion. Proof:
In fact, the object
P = (F A)
p
is such that, a cofinal subset of (l,B)
such that
B
Mp
is the constant inverse system
is the inclusion).
Mp
I (A)
consists of those pairs
is an inverse system constant past zero.
(An example of such a pair in A
in the category
E
p Z'
is the pair A,
And, for every such
(B/P)p=BO/F pA, P ~ 0, where
BO
and
(j,A),
j : (F pAl pEJ'
where -T
(A) pEl:'
(l,B), we have that
denotes the zero' th object in the
Filtered Objects inverse system regard
B -
-
(B
p' Bp, q ) p, qE;r' .
273
For every such
as a filtered object by defining and
B = BO '
(1, B) E Mp '
F BO = F A,
P
P
all
lim B/P = lim (BO/F pAl = pE;r' p~o
Therefore Coker ((lim B) pE;r'
(1)
+
(lim pE~
Next, by Corollary 2.1 (with
A
and
BO
interchanged), we
have the commutative diagram with exact rows:
(2)
and, also by Corollary 2.1 (with map
y
is an isomorphism.
A
and
interchanged) the
BO
Therefore, by diagram chasing in the
commutative diagram (2), we deduce that the natural mapping is an isomorphism: (3)
Coker (A
+
Since the elements
A1\ )
"" +
(1,
Coker (BO
B)
E=
Mp
+
1\ BO) •
such that
zero are cofinal in the directed class
B Mp '
is constant past it follows from
equations (1) and (3) that the direct system: {Coker ((lim B) pEl'
+
(lim B/P») pEl'
(1
B)EM 'p
trivializes, in the sense of Exercise 1, and therefore by Exercise 2 we have that (S lim) (P)
exists, and by equations (I) and (3)
pEl'
(S lim) (P) = Coker (A
pEl-
+
r!') .
Section 6
274
Changing notations as in Exercise 6, we therefore have that liml FpA pEJ'
exists, and that
liml F A = Coker (A ->- A") . pEJ' P
Q.E.D.
We are now ready to generalize Lemma 7, Corollary 7.1 and Corollary 7.2. Corollary 7.1'.
Let
A be an abelian category such that de-
numerable direct products exist, and let
A
be a filtered ob-
1
lim F p A exists, and we have pEJ' an exact sequence of four terms in the abelian category A: ject in the category
Then
A.
0->- (lim F A) ->-A->-A" ->- (liml FpA) ->- O. pEJ' P pEJ' Proof:
We have already observed, in Corollary 3.1, that the
kernel of the natural map
A ->- A"
is
n F A = lim F A. pEJ' p pEJ' P
Exercise 6, we have observed that liml FpA " pEJ' cokernel of the natural map A->-A . Corollary 7.2'.
lim pEJ'
Q.E.D.
A
is complete iff
lim F A = pEJ' P
F pA = 0 .
Proof:
Follows immediately from Corollary 7.1'.
Lemma 7'.
A be an abelian category such that denumerable
Let
direct products exist. in
exists and is the
The hypotheses being as in Corollary 7.1', we
have that the filtered object 1
In
A.
Proof: Remark.
Then
Let
A
be a complete filtered object
lim F A = liml pEJ' p pEJ'
Follows immediately from Corollary 7.2'. Let
A
be an abelian category such that
injectives (respectively:
A
has enough
enough injective monomorphisms) •
Fil tered Objects Then
I(A),
275
as defined in Exercise 6 above, has enough in-
jectives (respectively:
enough injective monomorphisms).
pose now that the abelian category numerable direct products. left exact functor
lim
p~;?
A
Sup-
is also closed under de-
Then, by Exercise 6, we have the
from
I(A)
enough injectives (respectively:
into
A.
Since
I(A)
has
enough injective monomorphisms),
derived functors R q lim, q':' 0, of the pE;? which are half exact functors from the category
we have the usual right functor
lim, pE;? into the category
I(A)
A.
By Example 1 above, we know also
that
(S lim) (P) exists, for all P E I (A), and that (S lim) pE;? pE;? is an additive functor from I(A) into A. Also, by Example
1, we know that
(S lim) pE;?
is the usual first derived functor
R 1 lim
of lim. Changing notations as in Exercise 6, we have pE;? p€;? exists in that, for every P E I (A) , that liml P = (S lim) (P) pE;? pE;? 1 from I (A) the sense of Exercise 6, and that the functor lim pE;?
into
A
as defined in Exercise 6 coincides with the usual first
riqht derived functor of
lim. pE;?
Therefore, in this case, the
1
"11m"
in the statements of pE;? Lemma 7', Corollary 7.1' and Corollary 7.2' above is simply the first right derived functor of "lim" PE:27 fined for example in [C.E.H.A.]. Example 3.
Let
X
be a topological space, such that there
exists a sequence of open subsets of tion is not open.
X
such that the intersec-
(Virtually all topological spaces that one
comes across obey this condition). all sheaves of abelian groups on jectives (see [GJ).
in the usual sense, as de-
Let X.
A
Then
be the category of A
It is trivial to show that
has enough inA
is closed
under inverse limits of arbitrary functors indexed by set-theo-
Section 6
276
retically legitimate categories. In particular,
A
products of objects. product" from
W
A
is closed under denumerable direct
However, the functor
into
A
"denumerable direct
is not exact (this is proved by a
modification of the argument in [RJ). Therefore, the hypotheses of the last Remark hold. I(A)
particular, by the last Remark, the category injectives; the functor:
lim
from
I(A)
into
A
In
has enough is left-
pE;r
exact; and the usual first right 1
defined in [C.E.H.A.]) is
derived functor of
lim (as pt;?l' (as defined in Exercise 6 above).
lim pEl' Therefore, in this Example, we have that Lemma 7', Corollary " lj,ml"
7.1' and Corollary 7.2' all hold, where the
in these
pE;r
results is the usual first right derived functor of
lj,m: 1'lE,7
I (A )'V'v> A
(as defined, e.g., in [C.E.H.A.]).
This is an example
where Lemma 7', Corollary 7.1' and Corollary 7.2' all hold and are non-trivial (but in which the hypotheses of the less general Lemma 7, Corollary 7.1 and Corollary 7.2 are not satisfied). Remark.
Let
X
be a topological space such that the intersec-
tion of denumerably many open subsets is always open. be the category of all sheaves of abelian groups on the functor "denumerable direct product ":
Aw'V'v> A
Let X.
A
Then
is exact.
We leave the proof as any easy exercise. More generally, by techniques similar to those in [RJ, it is not difficult to show that, if and
X
K
is any infinite cardinal
is any topological space, then the following three con-
ditions are equivalent: (1)
open;
The intersection of
open subsets of
X
is always
Filtered Objects (2) of
x
If
x E X,
then the intersection of
is always a neighborhood of (3)
If
I
277
AI'VU>A,
of all sheaves of abelian groups on
K
neighborhoods
x;
is a set of cardinality
"I-fold direct product",
<
where X,
< K,
A
then the functor is the category
is exact.
Section 7 The Partial Abutments of the Spectral Sequence of an Exact Couple
Definition 1. g ory and let
A
Let
be an (ordinary, ungraded) abelian cate-
(1) = (EP,q dP,q TP,q)
r
' r
' r
be a conventional bi-
p,qE~
r.::..rO graded spectral sequence starting with the integer
A.
abelian category
rO
in the
Then an abutment for the conventional bi-
graded spectral sequence
(1)
is a sequence
(Hn,TP,q)n,p,qE~,
where (1)
n H
is a filtered object in the abelian category
all integers (2)
( ~,q) 00
(p,q)~
n,
A,
such that
exists as defined in section 4, Defi-
nition 4'; and where (3)
is an isomorphism in the category
Remark:
A,
for all intp.gers
p,q.
From condition (2) of Defintion 1, it is clear that a
necessary condition for the conventional spectral sequence (1) to admit an abutment, is that the
Eoo-term,
(EP,q) 00
exists. gory
p ,qE~'
If this is the case, and if, e.g., the abelian cate-
A is closed under either denumerable direct sums of ob-
jects or under denumerable direct products of objects, then an abutment to (1) exists. exist , then take
Hn =
(E.g., if denumerable direct sums ED EP,q 00 , p+q=n
278
F H
p
n
ED E£' , q) • p'>p p'+q=n
=
The Partial Abutments
279
A is closed under both denumer-
Thus, if the abelian category
able direct products and under denumerable direct sums of objects (so that by Lemma 2' of section 4, exists), then an abutment exists for every conventional bigraded spectral sequence (1) in
A.
Of course, however, there are in
general many, non-isomorphic, abutments for a given such spectral sequence (1). Definition 2.
Let
(EP,q dP,q ,p,q Hn ,p,q) r ' r ' r " p,q,n,rE~
(1)
r~rO
and
(2)
('EP,q 'dP,q "p,q 'H n "p,q) r ' r ' r" p,q,n,rE~
be conventional
r~ro
bigraded spectral sequences with abutments starting with the same integer
A.
rO
in the (ordinary, ungraded) abelian category
Then a mapping of conventional bigraded spectral sequences
with abutments from (1) into (2) is a sequence
such that (a)
( fP,q) r
.
p,q,rE~'
(EP,q dP,q ,p,q) --i> r ' r ' r p,q,rE~
r~rO
r~rO
('EP,q 'dP,q "p,q) r ' r ' r p,q,rE~ r~rO
is a map (in the sense of Definition 5' of section 4) of bigraded spectral sequences in the abelian category A
of bidegree (0,0)
(in the sense of Proposition 0.3
of section 4) -i.e.,
( fP,q) r
p,q,rE~
r~rO
is a map of bidegree (0,0) in the bi-
Section 7
280
graded additive category
Spec. Seq. (r
and such that, for each integer (b)
fn: Hn->'H n
r>r - 0
) (A
-Z x-Z
)-
n,
is a map of filtered objects in the
abelian category
A,
such that, for every pair of integer (cl
0"
(r -r+l)
p,q, the diagram
'TP,q 'EP'q--------....,> G ('HP+ql
f~·q"l
P
1p(f
""
G
q)
P+
TP,q EP,q
;>
co
G (H P + q ) p
""
is commutative in the abelian category
A.
With this definition
' the conventional biO graded spectral sequences with abutments, starting with the
of mapping, for each fixed integer
fixed integer
r ' O
r
in the fixed abelian category
A,
additive, although in general not abelian, category. denote this category by
form an We will
CSs;O,O) (Al.
o Remark:
One can generalize U'e above definition of "mapping"
of conventional bigraded spectral sequences with abutments starting with the same integer additive category.
r ' O
so as to obtain a bigraded
Namely,
Definition 2.1.
If
bidegree
from the spectral sequence with abutment (1)
(h,k)
(h,k) E-Z x-z,
then we define a mapping of
into the spectral sequence with abutment (2) to be a sequence (3)
where (a)
is a mapping in
The Partial Abutments Spec. Seq. (
( _ +1) ) (A) r O' r, r > r_rO and, for every integer n,
281
of bidegree
is a map in the abelian category such that, for all integers
p
and
A,
n,
'H n + h + k p+h ' and such that, for every pair of integers p,q, (b2) fn
maps
into
(h,k),
F
the diagram
(c)
A,
is commutative in the abelian category the map induced by
f P+
q
q "f P+ "
where
is
on the subquotients, by virtue of con-
ditions (bl) and (b2). Then, with this notion of "mapping of bidegree we have that for every fixed integer
r
O'
(h,k)",
the conventional bi-
graded spectral sequences starting with the fixed integer in the fixed abelian category
(A). rO graded) category of maps of bidegree the additive category
CSS
CSS (0,0) (A) r
O
A form an additive, but in
general not abelian, bigraded category. tive bigraded category by
r
We denote this addi-
Then the (ordinary, un(0, 0)
of
CSS
r
(A)
is
O
defined in Definition 2
O
above. The next theorem is important, and is used extensively in mathematics. Theorem 1.
Let
A be an arbitrary (ordinary, ungraded) abelian
282
Section 7
category.
Let (1) and (2) above be conventional bigraded spec-
tral sequences with abutments starting with the same integer ro
in the abelian category
(i.e., objects in
A
(fP,q fn) r ' p , q , n , rEJ' r.:::rO quences (i.e., a map in the bigraded category
n H
object
(A)),
rO be a mapping of such spectral se-
and let
arbitrary bidegree
CSS
(A)) of rO Suppose also that the filtered
(h,k) E J' x J'.
CSS
is complete and co-Hausdorff, for all integers
and that the filtered object for all integers
n.
'H
n
n,
is co-complete and Hausdorff,
Then the following two conditions are
equivalent. (1)
For every pair of integers fP,q: EP,q rO rO
-+
'EP+h,q+k rO
abelian category (2)
p,q,
we have that
is an isomorphism in the
A.
The mapping
(fP,q fn) is an isomorphism of r ' p,q,n,rEJ' r.:::rO (h,k) in the additive bigraded category
bidegree CSS (A) • Note:
Condition (2) is equivalent to saying that: (2a)
For all integers fP,q. EP,q r
.
r
-+
p,q,r,
'EP+h,q+k r
abelian category
we have that
is an isomorphism in the
A,
and (2b.l)
For every integer n fn: H
-+
category
n,
n h k 'H + + A,
n,
we have that the map
is an isomorphism in the abelian
such that, for all integers
p
and
The Partial Abutments (2b.2)
Proof:
fn
maps
F
'H n +h + k
p+h
FpH n
283
isomorphically onto
•
Clearly, condition (2) implies condition (1).
Assume
condition (1); to prove condition (2). Then by Proposition 4' of section 4, we have that condition (2a) of the above Note holds.
Therefore by Corollary 4.1'
of section 4, we have also that f~,q: E~,q .... 'E~+h,q+k
is an isomorphism in the abelian category p
and
q.
A,
for all integers
But then, from the commutative diagram (c) of Defi-
nition 2.1 above, it follows that, for all integers the map induced by
fn
in the abelian category
p
and
n,
A by passing
to the subquotients, is an isomorphism (3)
For each integer abelian category object of 'H n + h + k , tegers fn
"Hn
n,
define a filtered object
"H
n
in the
A as follows, by requiring the underlying to be the same as the underlying object of
F (IIHn) =F ('H n + h + k ) for all inp p+h ' Then by condition (bl) of Definition 2.1, the map
and by defining p,n.
in the abelian category
A is a map
of objects in the abelian category of Definition 2.1, the map
A;
and by condition (b2)
284
Section 7
is a map of filtered objects in the abelian category
A.
The
fact that the map in equation (3) above is an isomorphism in A,
is equivalent to: (3' )
is an isomorphism in the category
By hypothesis, the filtered object
A,
for all integers
n H
p,n.
is complete and co-
Hausdorff, and the filtered objects 'Hn-and therefore also "Hn-are co-complete and Hausdorff.
Therefore, by equation (3')
and Theorem 4 of section 6, it follows that
is an isomorphism of filtered objects. ment back in terms of
'Bn
Translating this state-
gives conclusions (2b.l) and (2b.2)
of the Note. Remark 1.
Q.E.D.
Suppose that the hypotheses of Theorem 1 above hold,
and that also condition (1) of Theorem 1 holds. rem I, condition (2) holds. objects, where n Since H n and that H 1.
"H
n
Therefore
Then by Theoas filtered
is as constructed in the proof of Theorem
is complete and "H n
Hn~ "H n
"H n
is co-complete, i t follows
are both complete and co-complete-and there-
fore also
'H n
is both complete and co-complete, for all n E?'.
Remark 2.
Let
A
be an abelian category.
Then in section 6
we have defined the category of filtered objects in additive category.
A
and
an
We generalize, by defining, for each integer
d, the notion of a map of filtered objects of degree Namely, if
A,
B
are filtered objects in
fine a map of filtered objects of degree
d
from
A,
d. then we de-
A
into
B
The Partial Abutments to be a map category
f:A
A,
->
B
285
of the underlying objects in the abelian
such that, for every integer
p,
f
With this notion of maps of degree
into integers
d,
maps
d,
F A P
for all
the filtered objects in the abelian category
form a singly graded additive category gory of maps of degree zero of
Filt(A).
Filt(A)
A
Then the cate-
is the (ordinary, un-
graded) category of filtered objects as defined in section 6. Of course, using this definition of the singly graded category
Filt(A),
one can pose more easily the definition, Defini-
tion 2.1, of the bigraded additive category avoid the explicit mention of
"H
n
CSS(A),
and also
in the proof of Theorem 1.
(For example, in terms of shift isomorphisms, in the proof of "H n ='H n +h +k h '
Theorem 1,
shifted down by Let
A
.
1.e.,
. t 'lS,
1
II
'H n +h +k
with degrees
h").
be an abelian category such that denumerable direct
products and denumerable direct sums of objects exist.
Then in
general, if (1)
is a conventional bigraded spectral sequence with abutment in the (ordinary, ungraded) abelian category integer
r
' O
A
starting with the
then by Theorem 6 of section 6, we have that
canonically as filtered objects; and by Remark 1 following Corollary 6.1 of section 6, these isomorphic filtered objects are complete and co-complete. section 6, we have that
Also, by Remark 2 following 6.1 of
Section 7
286
G
P
(co-comp(H
111\
)) ""
G
n
P
H
canonically, for all integers inverse of this isomorphism.
p,n.
Let
eP,n-p
denote the
Then it follows that, if
A is
any abelian category such that denumerable direct products of objects and denumerable direct sums of objects exist, then if
(1) above is any conventional bigraded spectral sequence with
A starting with the integer
abutment in the abelian category r
o'
(H
if we replace the abutment:
n TP,q)
,
p,q,nEZ"
of
(1)
with the completion of its co-completion, or equivalently with the co-completion of its completion, then the spectral sequence:
(EP,q dP,q TP,q) itself is unchanged, but r ' r ' r p,q,r~ r.::.rO the abutment is replaced by a complete and co-complete abutment.
A is closed under denumer-
Therefore, if the abelian category
able direct products and under denumerable direct sums of objects, then every object (1) in
CSS
(A) can be replaced by rO an object having the same spectral sequence, but having a com-
plete and co-complete abutment, simply by replacing the abutment with the completion of its co-completion. ject (1) in the category
For every ob-
(A) where A is such an abelian rO category, we will denote the object thus obtained in CSS (A) rO 1\ by co-comp«l) ). Corollary 1.1.
Let
A
CSS
be an abelian category such that de-
numerable direct products and denumerable direct sums of objects exist.
Let (1) and (2) above be spectral sequences with abut-
ments in the abelian category
A
starting with the same inte-
(fP,q fn) be a map of spectral r ' p,q,n,rEz r.::.rO sequences with abutments of bidegree (h,k) in the sense of Let
287
The Partial Abutments Definition 2.1. above.
Suppose that, there exists
can be either an integer or else fP,q: EP,q ->- EP+h,q+k r r r l l l
(3)
integers
co-comp(f
IlI\
n,
~rO
(r
l
such that
is an isomorphism for all
the induced mapping
): co-comp(H
is an isomorphism of degree Filt(A)
l
p,q.
Then, for every integer (4)
+00)
r
h
DI\
) ->-co-comp('H
n-+ h+kA
)
in the singly graded category
of all filtered objects in the abelian category
A,
as defined in Remark 2 following Theorem 1. Proof:
Suppose first that
r
l
is an integer.
Then replacing
the spectral sequence (1) starting with the integer its restriction past
r
l
,
r O'
and the abutment of (1) by the com-
pletion of its co-completion, we obtain the object in (co-comp(l
with
CSS
r
(A) : l
A
r
) ) l
where
is the natural isomorphism, for all integers
p,q.
Performing
the same operations to (2) yields similarly an object )A
(fP,q fn) yields p,q,n,rEJI' r ' r>r 1\ 1\ (A) a map in CSS from co-comp(l ) into co-corhp(2 ) r r r l l l and all of the hypotheses of Theorem I above hold, with r rel placing rOo In addition, hypothesis (3) of this Corollary imco-comp(2
r
l
in
CSS
r
(A) •
But then
l
plies condition (l) of Theorem 1.
Therefore by Theorem I we
Section 7
288
have condition (2) of Theorem 1, and in particular both conditions (2b.l) and (2b.2) of Theorem 1.
These are equivalent to
conclusion (4) of this Corollary. If
r
l
= +00,
by co-comp (2) if
f~,q
/\
then replacing (1) by co-comp(l)
/\
and (2)
the argument in the proof of Theorem 1- that
,
is an isomorphism for all integers
then we have
p,q
conditions (2b.l) and (2b.2) of the Note to Theorem l-applies, completing the proof of the Corollary in this case. Remark 1.
If in Corollary 1.1, we delete the hypothesis that
the abelian category
A
is "such that denumerable direct
products and denumerable direct sums of objects exist," then if n
is any fixed integer such that
co-comp(H n )
HnI\,
co-comp(HnI\),
(co-comp Hn)/\, 'H n + h + k /\, co_comp('H n + h + k /\),
and
co_comp('H n + h + k )
and
(co-comp 'Hn+h+k)/\
all exist, then the
proofs of Corollary 1.1 and of Theorem 1 show that co-comp (f
nI\
): co-comp (H
nI\
)
+
co-comp ( 'H
is an isomorphism of filtered objects in h,
for the fixed integer
Remark 2.
n+h+k/\
Filt(A)
) of degree
n.
The significance of Theorem 1 above is that, if we
have a conventional bigraded spectral sequence with abutment in an abelian category
A,
then it is important to know whether
or not the abutment is complete and co-complete.
In practical
examples, the abutment is often an interesting object, of some significance.
If we should replace the abutment with the com-
pletion of its co-completion, (assuming, e.g., for simplicity that the category
A
is closed under denumerable direct products
and denumerable direct sums of
object~,
then this might not be
The Partial Abutments as interesting an object.
289
This is why it is important to check,
given a specific conventional bigraded spectral sequence that has an interesting abutment, whether or not that abutment is complete and co-complete.
If not, then one should try, if pos-
sible, to compute explicitly, and determine, if possible, the significance of the completion of the co-completion of the abutment (which, as noted just before Corollary 1.1 is then another abutment for the given spectral sequence). Of course, the most cornman conventional bigraded spectral sequences are those that corne from conventional bigraded exact couples.
It is not true that every spectral sequence of a con-
ventional bigraded exact couple comes endowed with a "natural" interesting abutment (not even if the abelian category
A
is
the category of abelian groups); special assumptions are needed for this.
However, as we shall see, at the fullest level of
generality, the spectral sequence of a conventional bigraded exact couple does induce two sequences of filtered objects, which together sort of sUbstitute for an abutment.
This obser-
vation is the reason for the next definition. Definition gory.
3.
Let
A be an (ordinary, ungraded) abelian cate-
Let
(1)
be a conventional bigraded spectral sequence starting with the integer
rO
E~-term
(EP,q)
-
in the abelian category 00
(p,q)EJ'Q
exact sequences:
A.
Suppose also that the
exists, and that we are given short
Section 7
290
(2)
, q "" 'EP,q
,g
O
v
0
0)
A for all integers
in the abelian category
p
and
q.
(We
will call such a set of short exact sequences (2) a partition ~+'
...J.,U..
(EP,g) co (p, g) EZ' x)' • )
Then bv a set of partial abutments .1 _ sequence (1)
conventional bigraded to
(E~,g) (p,qlE)'xZ'
partition (2) of
respect
we mean a sequence
(3 )
where (al
(b)
'Hn
and
"H
category
A,
'" p, q:
' E~ ,q
n
are filtered objects in the abelian all integers
-+
G
p
(' H P +
n,
g)
is an epimorphism in the abelian category all integers
(e)
"TP,g:
G
p
p,q,
("HP+g)
+
for
A,
for
and "EP,g co
is a monomorphism in the abelian category all integers Suppose that
A,
p,g.
('H n 'TP,q "H n "TP,g) ,
"
p,g,nE~
is a set of
partial abutments for the conventional bigraded spectral seguence (1) with respect to the partition of (2).
Then we call
'Hn,
nEZ',
or the right abutments, and abutments, or the ~~:
If
"H n ,
the direct limit abutments, n
t;;;[ ,
the inverse limit
abutments.
('H n ,'T P ,g,"H n ,II TP,g)
is a set of partial abutments
as above, then it is of course in general false that n , p ,g) ( 'H , T p, q, nE;[
is an abutment, in the sense of Definition
The Partial Abutments 1, for the spectral sequence (l).
291
The terminology "direct limit
abutments," or "right abutments", therefore should not be taken to imply such a statement. butments Remark 1.
Similarly for the inverse limit a-
("Hn,"TP,q). Notice that the notion of a set of partial abutments
for a conventional bigraded spectral sequence (1) with respect to a given partition of
(2)
is self dual.
More precisely, if (1) is a conventional bigraded spectral sequence in the abelian category
A,
and if we have short
(E~,q) (p,q)E~x~
exact sequences (2) defining a partition of
as above, then (2) defines similar short exact sequences (2)0 in the dual abelian category
AO
(with
'EP,q
and
"EP,q
00
00
interchanging significance in passing to the dual category). If
('H n 'TP,q "H n "TP,q) , " p,q,nE~
is a set of partial abutments
for (1) with respect to (2), then
("H n "TP,q 'H n 'TP,q) , " p,q,nE~
is a set of partial abutments for the dual spectral sequence (1)0 with respect to (2)0 in the dual abelian category
AO •
Notice, therefore, in passing to the dual category, that the direct limit abutments and the inverse limit abutments interchange roles. The significance of Definition 3 is made clear by the following Theorem. Theorem 2.
(The partial abutments of the spectral sequence of
a conventional bigraded exact couple.) ungraded) abelian category, and let
Let
A be an (ordinary,
Section 7
292
(1)
be an arbitrary conventional bigraded exact couple starting with the integer
rO
in the abelian category
A.
Let
(2)
be the (conventional, bigraded) spectral sequence starting with the integer
rO
of the exact couple (1), using the indexing
convention given in Example 3.1 at the end of section 5. Let
t= (tp,q) (p,q)E,'lx,'l
and
V= (Vp,q) (p,q)E,'lxl".
Suppose
that the (t-torsion part), the (infinite t-torsion part), the (t-divisible part) and the (infinitely t-divisible part) of the bigraded object
Vall exist, as defined in Definitions I'
and 2' of section 5 (this condition is automatically satisfied if, for example, the abelian category
A
is closed under de-
numerable direct products and denumerable direct sums of objects, see Example l' following Definition 2' of section 5). Theorem 4' of section 5, we have that:
(E~,q) (p,q)E,'lx,?'
The
Then, by
Eoo-term,
of the spectral sequence (2) exists, and that
we have the short exact sequence of bigraded objects: (*)
0+ [(Ker t)
n (t-divisible) 1 ~'k" (EP,q) part of
V/(t-torsiOn)] [ t. (v/torsion)
0 +
,
V
00
(p,q)E,'lx,?
;'h"
The Partial Abutments where the maps
"h"
and
Ok"
are maps of the bigraded objects,
induced respectively by the maps
hand
(1) by passing to the subquotients. be the image of
"k",
IIhll,
and
("EP,q) 00
"h"
then since
293
k
in the exact couple ( 'EP,q)
If we let
00
(p,q)E'Z'x'Z'
is a monomorphism and
(p,q) E'Z'x71
be the co image of uk"
is an epimor-
phism, we have natural isomorphisms of bigraded objects in
V/(t-torsion)l~ ('EP,q)
(* .1)
[ t·NI (t-torsion))J
co
A:
(p,q) E'Z'X'Z'
and ("EP,q)
(*.2)
OJ
(p,q)€?'x,z
n (t-divisible) 1 part of
V
'
induced by
hand
quotients.
(These isomorphisms are not, in general, of bidegree
(0,0».
respectively, by passing to the sub-
And then we have the short exact sequences in the
abelian category P,q O+-" E 00
(*' )
k
':; [(Ker t)
all integers
A, -<-
P , q +- 'E P , q +E 00 00
p,q E 71.
a
,
(*') is a partition of
in the sense of Definition 3 above, which we will call the partition of
(E~,q) (p,q)E'Z'x71
induced £y the exact couple (1).
Then there is induced a natural set of partial abutments: (3)
for the spectral sequence (2) with respect to the partition (*') of (E~,q) (p,q)E'Z'xij" below:
•
And
'To(*.l), (*.2) °T"
induce (4),(5)
For the associated graded of the direct limit abutments, we have the canonical isomorphism of bigraded objects in
A,
294 (4)
Section 7 (
Gp
('HP,q))
"" [ VI (infinite t-torsion) ] (p,q)EZ'xZ''''- t· (Vi (infinite t-torsion))
and for the associated graded of the inverse limit abutments,
A,
we have the canonical isomorphism of bigraded objects in
(5)
(G ("HP,q)) . --> (p,q)EZ'xZ' p [(Ker t) n (infinitely vt-divisible)l. part of We have that the direct limit abutment
'H
n
is always co-
complete as filtered object, and that the inverse limit abutment "H
n
~ote
is always complete as filtered object, for all integers 1.
The bidegrees of the map
of the map
"h"
h
n.
in the exact couple (1),
in the short exact sequence (*), of the canoni-
cal isomorphism (*.1) and of canonical isomorphism (4) are all the same. the map
Also, if k
(ex, S) E Z' x Z'
denotes this bidegree, then
in the exact couple (1), the map
"k"
in the short
exact sequence (*), the canonical isomorphism (*.2) and canonical isomorphism (5) all have the same bidegree (r
o-
a,-r + 1- S). O
Note 2. (p,q)
For each integer such that
p +q
=
in the abelian category (6 )
n
t P + 2 ,n-p-2
.::....------;!>
V
n,
n.
consider all pairs of integers
Then we have the infinite sequence
A,
p+l n-p-l '
vp-l,n-p+l
P+l,n-p-l --=t _____ !> Vp,n-p
tp,n-p
!>
tp-l,n-p+l --"-----!>
The objects that actually occur in this sequence are precisely n those vp,q such that p +q = n. Let 'K be the direct limit of the sequence
(6 ), n
The Partial Abutments
295
'Kn=lim Vp,n-p.
(7.0)
p""-oo
Introduce a filtration on
'K
n
by defining
to be the vP,q""'K n ,
image of the natural map into the direct limit, where
p +q =n , (7.1)
Then we define the direct limit abutments to be the filtered n 'K ,
objects
with some shifting of degrees.
(7.2) where
F
(a,B)
'H
n
= F
p-a
'K n - a -
is the bidegree of the map
(1), as in Note 1 above. limit of the sequence (8.0)
p
Similarly, let
B
'
h "K
Explicitly,
in the exact couple n
be the inverse
(6 ), n
"K n = lim vp,n-p. P",,+OO
Then introduce a filtration on
"K
n
by defining
to be
the kernel of the natural map from the inverse limit, "Kn ....vp-l,q+l,
where
p+q=n,
(8.1)
Then we define the inverse limit abutments to be the filtered objects
"Kn,
with some shifting of degrees.
Explicitly,
(8.2)
where
is the integer such that the conventional bigraded
exact couple (1) starts with the integer
rO
in the sense of
Example 3.1 of section 5 (and therefore also the spectral
Section 7
296
sequence (2) starts with the integer Proof:
Let
n
r )' O
be an integer, and consider the sequences (6 ) n
of Note 2, defined for every integer
n.
Then by Definition 2'
of section 5, the (infinite t-torsion part of
V)
exists, if
and only if the direct limit of the sequence (6 ) exists for n every integer
n.
By the hypotheses of this Theorem, the (in-
finite t-torsion part of
V) exists.
Therefore the direct limit,
of the sequence (6 ) exists for every integer n. Next, n n we introduce a filtration on 'K by equation (7.1) of Note 2, 'Kn,
so that A,
'K
n
becomes a filtered object in the abelian category
for all integers
n.
By definition of "infinite t-torsion", see Definition 2' of section 5, we have that (infinite t-torsion part of for all integers
p,n.
V)p,n- p
Equation (9) above and Equation (7.1) of
Note 2 imply that the natural map
Vp , n-p ... 'K n
induces, by
passing to the subquotients, an isomorphism (10)
[V/(infinite t-torsion)]p,n-p"'F p 'K n ,
for all integers
p,n.
From the sequence (6 ) and the definition n
(7.1) we deduce the commutative diagram
(11)
Equation (10), for the pairs of integers
p,n
and
p + l,n,
the diagram (11), imply that we have the commutative diagram
and
The Partial Abutments
297
[V/(infinite t-torsion)lP,n-p----------~ "" >F p 'K n
J
"tP+l,n-p-ll
(12)
[V/(infinite t-torsion)lP+l,n-p-l ____ "" ~0> F in which the map
"tP+l,n-p-ll
passing to the quotients.
is induced by
p+l
'K n
'
tP+l,n-p-l
by
The commutative diagram (12) implies
that we have a canonical isomorphism (13) [
V/(infinite t-torsion) ]p,nt ·CV/(infinite t-torsionD
for all integers
p,n.
p
"" G 'K n p ,
Otherwise stated, we have a canonical
isomorphism of bigraded objects in the abelian category
A,
of
(0,0) ,
bidegree (14)
V/ (infinite t-torsion) ] ':; lG 'KP+q ) p (p,q)E:7! x 71. [ t ·f.J/(infinite t-torsion))
Let
(a,S)
be, as in Note 1, the bidegree of the map
in the exact couple (1).
h
Then, since the exact couple (1) is
a conventional bigraded exact couple, if
(al,Sl) =deg k,
then,
see Example 3.1 of section 5, we must have that a+S+a
+Sl =1, a+a l =rO· Therefore a l =rO -a, Sl =-rO+l-S. l Therefore deg(k) = (al,Sl) = (rO-a,-rO+l- S ), as asserted in Note 1. (*)
Also, since the map
and the map
in the short exact sequence
(*.1) are induced from
subquotients, it follows that Similarly,
"h"
h
by passing to the
deg("h") =deg(*.l) =deg(h) = (a,S).
deg("k") =deg(*.2) =deg(k) = (rO-a,-rO+l-S),
as
asserted in Note 1. If we define the filtered object
'H
n
in the abelian cate-
298
Section 7
gory
A
by requiring that Equations
(7.2) hold, then we have
that G 'H n = G
p
p-a
for all integers
p
n a- S
'K -
and
isomorphism of bidegree
n.
Therefore we have the canonical
(a,S),
"" ( ,p+q) ( G ,p+q) (p,q) E71 x 'l -> Gp H (p,q) E71x'l p K
( 15 )
Composing the isomorphisms (14) and (15), we obtain the isomorphism (4) of bidegree (a,S). Next, notice that by Example 4' of section 5, we have that (t-torsion part of
Vic (infinite t-torsion part of
V).
Therefore, we obtain the natural epimorphism of bidegree
vI (t-torsiOn)] [ t -(vi (t-torsion)}
(16)
[ vi (infinite t-torsion) ] -;:. t.(ljl(infinite t-torsion)} •
The isomorphisms (*.1) and (4) have bidegree (a,S), epimorphism (16) has bidegree (0,0). (' p,q) T
(p,q) E71x'l
(0, 0)
to be composite of:
and the
Therefore if we define the inverse of the iso-
morphism (*.1), followed by the epimorphism (16), followed by the isomorphism (4), then ( ' T p,q) (p,q) E71x71""
(17)
is an epimorphism of bigraded objects in the abelian category A
of bidegree (0,0). If we define the filtered objects "K
integers
n
n
and
"H
n
for all
as in Note 2, then the dual of the arguments just
given establishes the isomorphism (5), establishes that the bi-
The Partial Abutments
299
degree of the isomorphism (5) is as asserted in Note 2, and also defines a monomorphism (18)
of bigraded objects in the abelian category
A
of bidegree
(In fact, these observations about the inverse limit
(0,0) •
n "H ,
abutments
n E?!,
can alternatively be deduced directly
from the corresponding observations about the direct limit abutn 'H ,
ments
the sequence
n E?!,
by passing to the dual category).
('H n 'yP,q "H n "yP,q) ,
"
p, q, nE?!
But then
is a set of partial
abutments for the spectral sequence (2) with respect to the partition given by the short exact sequences
as asserted in the Theorem. To complete the proof of Theorem 2, it remains only to show that the filtered objects 'H the filtered objects
"H
n
n
are co-complete, and that
are complete, all integers
n.
By equation (8.2) of Note 2, we have that the filtered objects
"H
n
and
l a "K n + - -
singly graded category rem 1)
n.
integers n
are canonically isomorphic in the
Filt(A)
(see Remark 2 following Theo-
through an isomorphism of degree
integer
"K
B
n
Therefore, to prove that
"K
for every
is complete for all
it is equivalent to prove that the filtered objects
are complete for all integers n
"H
rO - a, n
n.
is by definition the inverse limit of the sequence
300
Section 7 (8. 0)
II
Kn = lim Vp , n-p • p++oo
Therefore we have also that (19)
"Kn=li m [Im("Kn+vp,n-p)l. (1) p++oo
But by equation (8.1) we have that (20)
in the abelian category
Substituting into equation (19),
A.
we have that the natural map (21)
is an isomorphism.
Therefore by Definition 2, part (iv) of
section 6, we have that "K
n
is complete as filtered object.
The proof that the direct limit abutments plete for all integers
n
'H n
are co-com-
is similar; and in fact can be de-
duced from the corresponding assertion about the inverse limit abutments by passing to the dual category.
Q.E.D.
(1) The reason for this is that, in general, if in an arbitary category if
Bi
A,
where
D
is any directed set, and
are sub-objects of vi, for all i E D, such that the i i K+V maps into the subobject B , for all iED,
natural map:
and such that for all i, JED such that j ~ i, the map in the ij inverse system a maps Bi into Bj ; then we have also that i K = lim B , since K then satisfies the necessary universal iED mapping property.
The Partial Abutments Definition 4.
Let
(1)
301
be a conventional bigraded exact couple
in the abelian category
A
such that the hypotheses of Theorem
2 are satisfied-i.e., such that the (t-torsion part of
the (t-divisible part of and the
V)
V),
the (infinite t-torsion part of
(infinitely t-divisible part of
Then the set of partial abutments
~
abutments of the spectral sequence (2) induced We will refer to
limit abutment, resp.:
I Hn,
all exist.
V)
(IHn ,TP,q "H n "TP,q) , " p,q,nE7
constructed in Theorem 2, will be called the
couple (1).
V),
resp.:
of partial
~
the exact
"Hn,
as the direct
the inverse limit abutment,
induced
Qy the exact couple (1).
Notice that the filtered objects, the direct and inverse limi t abutments,
I Hn,
uHn,
n E:2,
depend (up to a shifting
of degrees) only on the bigraded object
V -
-
and the map of bigraded objects of bidegree t = (tp,q) (
p,q
)C.~x:2
from
'-U-
(Vp,q)
(p,q)E:2 xZ
(-1,+1),
into itself occurring in the exact
V
couple (1), and not at all on the bigraded object
Definition 5.
Let
(EP,q dP,q TP,q) be a conventional r ' r ' r r~rO bigraded spectral sequence in the abelian category A starting
with the integer (EP,q) (p,q)E:2 xZ
(1)
rOo
Suppose that the
Eoo-term
exists for the spectral sequence (1), and that
00
we have short exact sequences (2)
o+
"E P , q 00
+
EP , q
in the abelian category is a nartition of ...
I EP , q
+
00
(EP,q) 00
+
0
00
A
for all integers
(p,q)E:2xZ'
p,q,
so that (2)
and that we have also
Section 7
302
(3)
a set of partial abutments for the spectral sequence (1) with respect to the partition (2) of say that the direct limit abutments limit abutments
"Hn)
(EP,q) We will co (p,q)E;.I',,?,· n 'H (resp.: the inverse
are perfect iff the epimorphisms
are isomorphisms, for all integers
p,q,
(respectively:
iff
the monomorphisms
are isomorphisms, for all integers Suppose
p,q.)
that (1) above is a conventional bigraded spectral
sequence such that the Eco-term exists, and that we have the partition (2) above of the Eoo-term of (1), and also the set of partial abutments (3) above with respect to the partition (2). Then we define the right defect, or the direct limit defect, to be the
kernels of the epimorphisms
This is a bigraded object in the abelian category
a
subobject of
A,
and is
Similarly, we define the
left defect, or the inverse limit defect, to be the cokernels of the monomorphisms q ) -+ "EP,q "TP,q: Gp ("H P +r o'
p,q E 'J'.
This is also a bigraded object in the abelian category is a quotient-object of the bigraded object
A,
and
Eoo= (E~,q) (p,q) EJ'x?!.
The Partial Abutments
303
Clearly, from the definitions, the direct limit (resp.:
in-
verse limit) abutments are perfect iff the direct limit (resp.: inverse limit) defect is zero. RemarkJ:. Under the hypotheses of Theorem 2, using equations (*.2) and (5) of Theorem 2, it follows that, we have the canoni-
A,
cal isomorphism of bigraded objects in
[(Ker t) (in ver se 1 imi t de f ec t) '"
:>
n
(t-divisible)] part of V
-------:--=-;--.,-:-~-..,--~;__.,._~_=_
[(Ker t)
n
(infinitely t-divisible)] part of V
the isomorphism being induced by the map
k
in the exact couple
by passing to the subquotients, and therefore having bidegree bidegree(k)
equal to
(r
=
o
- a, - r
0
+ 1 - 13).
Similarly, under the hypotheses of Theorem 2, using equations(*.l) and (4) of Theorem 2, we have the canonical isomorphism of bigraded objects in
(direct limit
'"
defect)~
A, (infinite t-torsion in V) .(infinit~ t-torsion n t 1.n V
(t-~orsionH-[ 1.n V
the isomorphism being induced by the map
h
in
'
the exact couple
by passing to the subquotients, and therefore having bidegree equal to bidegree (h)= (a, 13) • Remark 2. In [LL.], if
A
is any abelian category such that
denumerable direct products exist, then given any inverse systern
C = (C
category object,
i
,
A,
a
ij
indexed by the integers in the abelian ). . E 1.,J 'l' j.:.i we define the deviation of C to be the'l'-graded
Section 7
304
Dev C _ a-divisible part of C - a-infinitely divisible part of where
C
~-graded
C '
on the right side of the equation is regarded as the
i (C )iE~'
A,
object in
morphism of degree -1 of this
and where
~-graded
a
object,
is the endo_ i, i-I a-(a )1' E 'Z' '
In terms of this definition, if the hypotheses and notations are as in the last Remark, then for each integer
n
we have
the inverse system of Note 2 to Theorem 2 t P + 2 ,n-p-2
-=-----0> V
cP n
= Vp,n-p
'
A.
p+l n-p-l tp,n-p ' 0> vp,n- p ....;;;--->
.....::;----_0> tP
'n
='
tp,n- p ,
therefore have an inverse system category
t
tp-l,n-p+l
vp-l,n-p+l
Defining
p+l n-p-l
for each integer C* n
=
(C
p P t ) n'npE;r
n
we
in the abelian
Then it follows immediately from the equation a-
bout the left defect deduced in the last Remark, that if
t
denotes the endomorphism of degree -1 of the graded object Dev(C*n)
(tP,n- p )
induced by
then we have that the biPE-r' graded object, the left defect of the part. abuts. of the spectral sequence of the exact couple (1) of Theorem 2, is canonically isomorphic, as bigraded objects, to the bigraded object in (precise t-torsion part of
Dev C*
p+q
)
(P,q)6~
the isomorphism being induced by the mapping
k
A,
q'
in the exact
couple (1) .. [left defect of
"k"
(l)~ ~
[precise t-torsion in Dev C* ] p+q (p,q)E;, x'Z'·
Therefore this isomorphism is of bidegree equal to bidegree
The Partial Abutments (k) = (r
O
- a,-r
corollary 2.1.
O
+1 -
305
s) • (*)
Under the hypotheses of Theorem 2, a sufficient
condition for the direct limit abutments to be perfect is that (t-torsion part of
V)
(infinite t-torsion part of
V).
A sufficient condition for the inverse limit abutments to be perfect is that (infinitely t-divisible part of Corollary 2.2.
V)
(t-divisible part of
V).
Under the hypotheses of Theorem 2, necessary
and sufficient conditions for the direct limit abutments to be perfect is that, the two subobjects of (t-torsion part of
V,
V)c (infinite t-torsion part of
have the same images in
V),
V/tV.
A necessary and sufficient condition for the inverse limit abutments to be perfect is that (Ker t)
n
(t-divisible part of
V)
=
(Ker t) n (infinitely t-divisble part of Proofs of Corollaries 2.1 and 2.2: prove Corollary 2.2.
V).
Obviously, it suffices to
By equations (*.1) and (4) of Theorem 2,
the direct limit abutments are perfect iff the natural epimorphism:
(*) Here, as elsewhere in this book, if C is an object in an abelian category, or in a graded abelian category, and t is an endomorphism of C, then by the precise t-torsion part of C we mean Ker t.
Section 7
306 V/(t-torsiOn)] [ t·cvI (t-torsion)) --~
l
V/(infinite t-torsion) ] t·CV/ (infinite t-torsion))
of bigraded objects of bidegree (0,0) is an isomorphism. equivalent to say, iff the (t-torsion part of (infinite t-torsion part of Also, by equations
V)
V)
It is
and the
have the same images in
V/tV.
(*.2) and (5) of Theorem 2, we have
that the inverse limit abutments are perfect iff the natural monomorphism: [(Ker t)
n
(infinitely t-divisible) l~ part of V
[(Ker t)
n
(t-divisible) 1 part of V
is an isomorphism.
Q.E.D.
A consequence of Corollary 2.1 is corollary 2.3.
The hypotheses being as in Theorem 2, suppose
that the abelian category
A is closed under denumerable dir-
ect sums of objects, and is such that the denumerable direct limit over the directed set of positive integers is an exact functor.
Then the direct limit abutments
for all integers Proof:
'H
n
are perfect,
n.
By Proposition I' of Example 5' of section 5, we have
that (t-torsion part of
V) = (infinite t-torsion part of
Corollary 2.1 finishes the proof. Example.
V). Q.E.D.
If we have any conventional bigraded exact couple in
the category of abelian groups, then the hypotheses of Corollary 2.3 hold.
Therefore, the direct limit abutments of every
The Partial Abutments
307
conventional, bigraded exact couple in the category of abelian groups, are perfect.
(The same is not true in general for the
inverse limit abutments, since inverse limit over denumerable directed sets is not an exact functor in the category of abelian groups.
See section 8 below for counter-examples.)
Remark 1.
Let the hypotheses be as in Theorem 2. 'H n ,
that, both the direct limit abutments verse limit abutments,
"Hn,
nE;?',
Then notice
n E~ ,
and the in-
as filtered objects,
de-
pend, up to a shifting of degrees, only on the bigraded object V= (Vp,g) of
V
(-1,+1)
of bidegree
also, the right part,
00
(p,g)E~x~'
(p,g)E~x~
in the exact couple (1) •
[ V/(t-torsion) ] to(Vi (t-torsion))
[ (Ker t) n (t-divisible part of ( EP,q)
t - (tp,g) -
and the endomorphism
(p,g)E~x~
V) ],
,
And
and the left part,
of the Eoo-term
as defined in Remark I' following Theorem 4'
of section 5, depend only on
V
and
t. (Vp,g) (p,g)E~X~
Graphically, the bigraded object with the endomorphism
(tp,g) (P,g)E~xZ
of bidegree (-1,+1)
can be pictured by a diagram, a portion of which is:
~l -21 V
-11
.
tal' ""'tIl '
~-11 ~Ol V
'~-20
"(10 v- lO
~-2-1
,t-l-l
tOO
~V00 0-1
~v-2-1 ~v-l-l ~\10-1
''(-2
~1-2
~-2
~l
\,11
~O v
lO
,(-1 vl - l ,,(-2
together
v 21
~
'(0 v
20
~-l
v 2- 1
~
~
~3-1
"""
~2
308
Section 7 Each of the lines
(Vp,q tp,q) , p+q=n
of slope -1, deter-
mines one of the groups of the direct limit abutment and one of the groups of the inverse limit abutment; namely, the direct limit of the n'th line, object
'Kn,
image of
(Vp,q tp,q) , p+q=n'
vp,q
in
'K n ;
n
is the filtered obJ'ect "K
n ('H ) .
and the inverse limit abutments n E.Z
and
n ("K )
"Kn,
where
is the kernel of the natural
"K
n ('K )
vp,q.
n
map from
from
into
is the
and the inverse limit of the n'th
the p'th filtered piece of
n~
'K n
where the p'th filtered piece of
(Vp,q tp,q) , p+q=n'
line,
is the filtered
And then the direct limit abutments
nEd'
("H n )
n~~
are obtained
by making the dimension shifts,
Equations (7.2) and (8.2), respectively, of Note 2 to Theorem 2. Remark 2.
Let
be an integer, and let
t (1)
(1)
be a conventional bigraded exact couple starting with the integer
rO
in an arbitrary abelian category
A.
It is equivalent
to say, "Let (1) be an object in the additive bigraded category EC
(rO,-rO+l) , (-1,+1)
section 5",
(A~x~)
where as usual
as defined in Definition 5.2 of
i' x
'l'denotes the abelian bigraded
category of all bigraded objects in
A.
Then (1) is canonically
isomorphic to a conventional bigraded exact couple
(1' )
The Partial Abutments starting with the integer
rO
309
in the abelian category
A,
the
isomorphism being of bidegree (0,0) and such that the bidegree of the map
h'
V' = V
let
in
(-a,-S)
(-a,-S) "- where of
and let
E,
(I')
is
- that is,
(0,0). "V
(a, S) = deg h. g=
(n
kt,..e»
-1
t' = got
0
g
,
h' = hog
-1
,
E' =E,
and
with degrees shifted down by Also, let
k' = g
0
f
be the identity
g:V~V'
Then
phism of bigraded objects of degree -1
Namely, let
(a,S). k.
is an isomor-
Define
Then
(I' )
is a conventional bigraded exact couple starting with the integer
r0
deg(hog
-1
in the abelian category
A,
and
deg (h') =
) =deg(h) -deg(g) = (a,S) - (a,S) = (0,0),
deg(k')
deg(gok) =deg(g) +deg(k) = (a,S) + (rO-a,l-rO-S) = (rO,l-r O). And the pair tive category
(g,id ) E
is an isomorphism in the bigraded addi-
EC(ro,-ro+l),(-l,+l) (A;!'Sl)-Le., in the cate-
gory of all conventional bigraded spectral sequences starting with the integer category
rO
in the (ordinary, ungraded) abelian
A -of bidegree (0,0)
(see Corollary 5.0.1 of section
5), as asserted. Therefore the spectral sequences of the exact couples (1) and (1') are canonically isomorphic.
In fact, if we trace the
construction, we see that the spectral sequences of the exact couples (1) and (1') are even identical (not merely canonically isomorphic). Therefore, if we wish, given any conventional bigraded
310
Section 7
exact couple starting with the integer gory
A,
rO
in an abelian cate-
we can always replace it with one canonically isomor-
phic in which the mapping
h
is of bidegree
(0,0) •
notation of Note 1 to Theorem 2, this means that
(In the
(a,S) = (0,0).)
If we were to make this convention, then in Theorem 2, we would have that deg h = (0,0)
and for the direct limit abutments, Equation (7.2) of Note 2 to Theorem 2 would then simplify to: "The filtered objects
'K
n
and
'H
n
coincide".
And for the inverse limit abutments, Equation (8.2) of Note 2 to Theorem 2 would then simplify to: for all integers n,p." However, we will not make the notational simplification of this Remark.
(The advantage of not insisting on such conven-
tions, is that one then does not have to re-index certain conventional bigraded exact couples that one comes across in applications). Remark 3.
As we have observed in the Note following Definition
3, a set of partial abutments for a conventional bigraded spectral sequence is not, in general, an abutment in the sense of Definition 1.
The next Theorem tells us, under the hypotheses
of Theorem 2, when the direct limit partial abutments are an ( honest) abutment in the sense of Definition 1.
The Partial Abutments Theorem 3.
311
Let the hypotheses be as in Theorem 2.
Then the
following two conditions are equivalent. (I)
n 'H ,
The direct limit abutments 'TP,q,
P,qEJI"
nEP,
together with
are an abutment for the conventional
bigraded spectral sequence (2) of Theorem 2 in the sense of Definition 1. (II)
(a)
The direct limit abutments
n 'H ,
nEJI',
of the
spectral sequence (2) of Theorem 2 are perfect (this condition is automatically satisfied if in the abelian category
A,
denumerable direct
sums of objects exist and the functor "denumerable direct limit" is and Example.
(Ker t) n (t-divisible part of
(b) If
tion (II) (a)
~),
A
V)
{o }.
is the category of abelian groups, then condi-
always holds.
equivalent conditions
Therefore, in this case, the two
(I) and (II) of Theorem 3 are each
equivalent to (II) (b), which in this case can be written (II) (b')
If
p,qEJI',
vEvP,q, ~
0,
tp,q(v) =0,
each integer
i
w. E vp+i,q-i
such that
and if for
there exists an element (tP+l,q-lo ••• 0
1
tP+i-l,q-i+1
Proof:
0
tP+i,q-i) (w) =
V1
then
v = O.
By definition of "a set of partial abutments", see
Definition 3 above, we have that
is an epimorphism, for all integers
p,q.
Condition (I) is
Section 7
312 equivalent to saying
is an isomorphism from
that
Therefore, for condition (I) to hold, it is
onto
necessary and sufficient that (a)
'TP,q
is an isomorphism, for all integers
p,q;
and that (b)
'EP,q = EP,q 00 00
for all integers
p,q.
Condition (a) is the definition of what it means for "the direct limit abutments to be perfect", see Definition 5 above. Condition (b) is equivalent to asserting that, "the subobject 'EP,q 00
of
EP,q 00
is the whole objectff; or, equivalently, that
"the corresponding quotient-object integers
p,q".
"EP,q 00
But by the isomorphism
is zero, for all (*.2) of Theorem 2,
this latter statement is equivalent to Condition (II) (b) above. Finally, note that, by Corollary 2.3, Condition (II) (a) of this Theorem always holds if denumerable direct sums of objects exist and the functor
A.
the abelian category Corollary 3.1.
"denumerable direct limit" is exact in Q.E.D.
Let the hypotheses be as in Theorem 2.
Then
the following two conditions are equivalent. (I)
The inverse limit abutments with
"TP,q,
p,q E 71'
"H n ,
nE;}',
together
are an abutment for the con-
ventional bigraded spectral sequence (2) of Theorem 2 in the sense of Definition 1. (II) (a)
(Ker t)
n
(t-divisible part of
V) =
(Ker t) n (infinitely t-divisble part of
V)
The Partial Abutments
(b)
Example.
If
v/(t-torsion) to(v/ (t-torsion)} =
313
o.
A is the category of abelian groups, then condi-
tion (II) (a) can be rewritten: (II) (a')
For every pair of integers tp,q (v) = 0
if
in
every integer wi
E vp+i,q-i
i,
p,q,
vp-l,q+l ,
if
v E vp,q,
and if, for
there exists an element
such that
'
(t P+I,q-1 o ••• 0 tP+i-l,q-i+1 0 tP+i,q-i) in
vp,q;
then there exists a sequence of
elements a nd such that integers Also, if
such that
i .:. 0,
i >
tP+i+l,q-i-1 (v
i+l
)
=
v. for all ~
o.
A is the category of abelian groups, then con-
dition (II) (b) can be rewritten: (II) (b')
For every pair of integers
p,q,
if
then there exist elements v
2
E v p + l ,q-l
v E vp,q, and
such that
v = v
I
+I q-l +tP ' (v) 2
'
and such that there exists an integer
i >0
such that (tp-i+l,q+i-l
0
t p - i + 2 ,q+i-2
0
•••
0
tp,q) (vI) = 0
in
vp-i,q+i.
Proof:
By the dual of Theorem 3, we have that condition (I)
of this Corollary is equivalent to the two conditions:
Section 7
314 (a)
The inverse limit abutments
"Hn,
n E'l',
are perfect,
in the sense of Definition 5, and (b)
The right part of
(EP,q) p , q) E'l' x'!' ' 00
as defined in
(
Remark l' following Theorem 4' of section 5, is zero. But (b) above is exactly equivalent to (II) (b) of this Corollary.
And the second part of Corollary 2.2 tells us exactly
that (a) above is equivalent to (II) (a) of this Corollary. Q.E.D. Remark.
In many expositions about spectral sequences, before
discussing abutments, enough hypotheses are made on exact couples to force condition (II) (b) of Theorem 3 to hold. if the category
A is the category of abelian groups, by
Then, Theo-
rem 3 the direct limit abutments form an abutment in the sense of
Definition 1.
For this reason, the reader will find, in
many references, that a single abutment only is discussed-the dir,ect limit abutment.
We do not wish to do this; partly
for
reasons of generality; partly because we think that the more general situation is easier to understand because of its selfdual nature; and partly because there
~
spectral sequences
in which the inverse limit abutments are important-e.g., some of the Adam's spectral sequences obey the hypotheses of Corollary 3.1 rather than those of Theorem 3, and therefore the inverse limit abutments are an abutment in the sense of Definition 1 for those spectral sequences (the direct limit abutments in fact being zero).
Also, the Bockstein spectral sequence (see
Chapter 1 below) is another example,of a singly graded spectral sequence, in which the left part of
(E~)nE'!'
is often important,
The Partial Abutments
315
and in particular is often non-zero. Suppose that we have a conventional bigraded exact couple as in Theorem 2; then it is obviously important to know, e.g., when the direct limit abutments (respectively:
the inverse
limit abutments) are complete; co-complete; discrete; co-discrete; or finite.
These results are easily read off from Theo-
rem 2 and the diagram in Remark 1 following Corollary 2.3. Proposition 4. (1) p,q
Let
n
such that
such that
tp-l,q+l
0
p +q = n
i >0 tp,q
'H n + a + S
=
and such that
such that 0).
tp-i+l,q+i-l
that
p I ,q I
t P + 2 ,q-2
t p - i + 2 ,q+i-2
0
p':::.p =
•••
0
•••
0
is discrete and co-complete; and the (n-l+a+S) 'th a n "H - l + + S
is co-discrete and complete.
Suppose, for every pair of integers
= p+q, t
0
Then the (n + a + S) 'th direct limit abut-
0;
and such that
v
PI
,q'
=0
or, weaker still, such that
otP'-l,q'+l otP',q' =0).
(t-torsion part of
V)
have the same images in
(p,q),
(p' ,q'), such that
that there exists a pair of integers p'+q'
(~, weaker,
vp,q = 0
or, weaker still, such that there exists
inverse limit abutment (2)
Then
be an integer such that there exist integers
tp,q = 0;
an integer
ment
Let the hypotheses be as in Theorem 2.
(££, weaker, such t
p+ 1 q 1 ,-
0
Suppose also that, the
and the (infinite t-torsion part of V/tv
cally if the abelian category
V)
(a condition that holds automati-
A is such that denumerable di-
rect sums exist and denumerable direct limit is exact).
Then:
The direct limit abutments are discrete and co-complete, and are an abutment for the spectral sequence in the sense of Definition 1. (3)
Suppose that, for every pair of integers
(p,q),
that
Section 7
316
there exists a pair of integers p+q=p' +q',
P':'P
' tP
such that
(p',q'),
and such that
,q' = 0;
vp',q' =0
(or, weaker,
or, wea k er Stl. 11 , sue h t h at
q+l p q tP '+l,q'-l o ••• op-l t' ot'=O).
Then:
such that
t P ' , q'
0
Suppose also that,
(Ker t)
n
(Ker t)
n (infinitely t-divisible part of
(t-divisible part of
V) = V).
The inverse limit abutments are co-discrete and complete,
and are an abutment for the spectral sequence in the sense of Definition 1. Proof:
(1)
By Theorem 2, the direct limit abutments are always
c-complete and the inverse limit abutments are always complete. By Equation (7.1) of Note 2 to Theorem 2, (7.1) Taking
p
as in part (1) of this Proposition, we have
and therefore
F 'K p
n
= 0
(QE,
then, since the natural map: t
P-i+l,q-i+l
0 .....
if
tp-i+l,q+i-l o •••
Vp,n-p
+
'K n
0
vp,n-p=O,
tp,q = 0,
factors through
otp,q, then once again we have that F 'K n = 0). p
By equation (7.2) of Note 2 to Theorem 2, F Therefore
p+a.
'Hn+a.+S=F 'Kn=O. p
'Hn+a.+S
is discrete, as asserted.
By duality, it
follows, likewise, that the inverse limit abutment
"Hn-l+a.+S
is co-discrete and complete.
integer
(2)
The hypotheses of (2) imply those of (1) for every
n.
Therefore the direct limit abutments are discrete
and co-complete.
The Partial Abutments
317
On the other hand, for every pair of integers have that there exists a pair of integers p' +q'==p+q, t,
t
p'-p
p' :.. p,
v p ' ,q'
,
->
(1m tP'-p)p,q == 0,
and such that the
vp,q,
such that
Hence
(t-divisible part of
This being true for all pairs of integers (t-divisible part of
we
(p '-p) 'th iterate of
v p ' ,q'
is zero on
and therefore
(p',q')
(p,q)
(p,q),
V)p,q==O.
we have that
V) = O.
But therefore the left part of (Ker t) n (t-divisible part of That is, Condition (II) (b)
V) = O.
of Theorem 3 holds.
By the hypo-
theses in (2), we also have ConditIon (II) (a) of Theorem 3. Therefore, by Theorem 3, we have Condition (I) of Theorem 3that is, the direct limit abutments ment in the sense of Definition 1.
n E~,
'Hn,
are an abut-
That completes the proof
of part (2) of the Proposition. (3)
Part (3) of the Proposition follows from Part (2)
by duality. Remark.
Q.E.D.
Under the hypotheses of Theorem 2, if
n
is any inte-
ger, then necessary and sufficient conditions for the (n+a+B) 'th group of the direct limit abutment, discrete, is that there exist an integer is entirely infinite t-torsion.
p
a 'H n + + B,
such that
to be vp,n-p
Similarly, necessary and suffi-
cien t conditions for the (n - 1 + a + B) 'th group of the inverse limit abutment,
a n "H - l + + B,
exist an integer
p
of
Vp,n- p )
is zero.
to be co-discrete, is that there
such that the (infinitely t-divisible part
318
Section 7
Proposition 5.
Let the hypotheses be as in Theorem 2.
be any fixed integer and let
p
vp,n- p ,
duce a filtration on
be any integer.
Let
n
Then we intro-
by defining the i'th filtered
piece to be:
j
the whole object, 1m (t
p+l,n-p-l
if
i ~ p;
p+2,n-p-2
0
t o •••
if
i~p.
Then the following two conditions are equivalent: (1)
The
(n+a+S)'th object of the direct limit abut-
'H n + a + S ,
ment,
(2)
is complete.
The quotient object vp,n-p/(infinite t-torsion)
is complete for the filtration induced from Proof:
Vp,n-p.
By definition of "infinite t-torsion",
(Definition 2'
of section 5), we have that [Vp,n-p/(infinite t-torsion)] =Coim(Vp,n-p .... 'K n ). By Equation (7.1) of Note 2 to Theorem 2, we have that
Therefore the factorization map, of the natural map Vp,n-p .... 'K n (3)
into the direct limit, is an isomorphism,
[V p , n-p / (infini te t-torsion)] ':;. F 'Kn. p
Also, by Equation (7.1) of Note 2 to Theorem 2 and the definition of the filtration on
Vp,n-p
given in this Proposition, we
The Partial Abutments
319
have that the isomorphism (3) is an isomorphism of filtered objects. F 'K
n
Therefore Eguation(2) of this Proposition holds iff is complete as filtered object.
p
6, this latter holds iff
'K
n
By Lemma 1 of section
is complete as filtered object.
And by Equation (7.2) of Note 2 to Theorem 2, this latter holds is complete as filtered object. corollary 5.1.
Q.E.D.
Let the hypotheses be as in Theorem 2.
n
be any fixed integer and let
p
duce a filtration on
by defining the i'th filtered piece
vp,n-p
be any integer.
Let
Then we intro-
to be:
!
(the
~ero. subobject of
Ker(t~,n-~ oti+l,n-i-l
if
i > p;
if
i,::p.
o •••
Then the following two conditions are equivalent: (1)
The
(n-l+a+B)'th object of the inverse limit abut"H n - l + a + B,
ment, (2)
.
~s
co-comp 1 e t e.
The subobject (infinitely t-divisible part of
Vp,n- p )
is co-complete for the filtration induced from vp,n-p.
Proof:
Corollary 5.1 follows by applying Proposition 5 to the
dual category. Remark 1. tions on
The reader should of course note, that the two filtravp,n- p ,
the one defined in Proposition 5 and the one
defined in Corollary 5.1, are, most often, totally different,
320
Section 7
and bear in general no interesting relationship to each other. Remark 2.
It is of course easy to give conditions under which
a direct limit abutment is co-discrete. Proposition 6. n
Videlicit,
Let the hypotheses be as in Theorem 2, and let
be a fixed integer.
Then a sufficient condition for the 'H n + a + 6 ,
(n + a + 6)' th object of the direct limit abutment, be co-discrete, is that there exist an integer for every integer
p'
t P ' ,n-p':
vp '
with
p'
~p,
p,
to tha~
such
we have that the map
,n-p' .... VP'-l,n-p'+l
is an epimorphism. A necessary and sufficient condition for the
n a 'H + + 6
object in the direct limit abutment is that there exist an integer p'
with
p'
~P,
p,
(n +
Ci
+ 6) 'th
to be co-discrete,
such that, for every integer
we have that the mapping induced by
' ,n-p', t P
[Vp',n-p'/(infinite t-torsion)]~ [Vp)-l,n-p'+l/(infinite t-torsion)]
is an epimorphism.
(Note:
This latter mapping is always a
monomorphism; so the condition is equivalent to asserting, that that mapping is an isomorphism, for all
pI
~
p.)
The proof is easy, and follows immediately from the diagram of Remark 1 following Corollary 2.3, and from Equations
(6 ), n
(7.1) and (7.2) of Note 2 to Theorem 2. Similarly, by duality, we obtain Corollary 6.1. n
Let the hypotheses be as in Theorem 2, and let
be a fixed integer.
Then a sufficient condition for the
(n - 1 + a + 6) I th obj ect of the inverse limit abutment,
The Partial Abutments n l a "H - + + S ,
321
to be discrete is that there exist an integer
such that, for every integer
p'
with
p' '::'p,
p,
we have that
the map p' n-p' p'-l n-p'+l P '' n-p' : V t ' +V ' is a monomorphism. A necessary and sufficient condition for the (n-l+a+S) 'th object in the inverse limit abutment,
"H n - l + a + S ,
crete, is that there exist an integer
p,
every integer restriction of
(
p'
with
p'
~p,
to be dis-
such that, for
we have that the mapping, the
' ,n-p' tP
infinitely t-divisible part) ___~(infinitelY t,-diVis~,'ble) of vp ',n-p' part of Vp - 1 , n - p +1 (~:
is a monomorphism.
This latter mapping is always an
epimorphism; so the condition is equivalent to asserting, that that mapping is an isomorphism for all Remark 3. hold, then
p' '::'p.)
If the hypotheses of Proposition 6 of Remark 2 above Fp+a'Hn+a+S
= 'H n + a + S ;
and similarly, if the hypo-
theses of Corollary 6.1 of Remark 2 above hold, then F
p -r n+a
l a "H n - + + S - 0 - •
These results are best possible- that
is, for any fixed integers conditions that
F
p+a
"H n - l + a + S - 0 Fp -r +a - ,
p
n a 'H + + S
and
n,
= 'H n + a + S
'
necessary and sufficient respectively:
is that for every integer
()
spectively:
p' ~p,
that the map induced by
p'
that
~P,
tp',n-p'
re-
,
[Vp',n-p'/(infinite t-torsion)]--> , [V p'-l,n-p'+l/(,~n f'~n~te
'
t-tors~on
)]
be an epimorphism (or, equivalently, isomorphism),
respec-
Section 7
322 tively:
(
that the restriction of
t
PI ,n-p' ,
infinitely t-diVisibl, -\infinitelY t-divisible) p'-l n-p'+l ' n-p' part of V P ' part of V '
be a monomorphism (or, equivalently, isomorphism). Remark 4.
We leave it to the reader, to put together Proposi-
tiorn4 and 6, and the Remark following Proposition 4, to write down sufficient; and also necessary and sufficient; conditions for the direct limit abutments of the spectral sequence in Theorem 2 to have finite filtrations; and similarly for the inverse limit abutments, with Corollary 6.1 replacing Proposition 6. Remark 5.
The partial abutments of the spectral sequence ofa
conventional bigraded exact couple were first introduced by
O. A. Laudal in an earlier unpublished version of IO.A.L).
He
uses a considerably different notation than ours. Remark 6. In Section 9, Corollary 4.1, we will show that, under the hypotheses of Theorem 2, if the abelian category
A is such
that denumerable direct products exist and such that functor, "denumerable direct product":
AW'\fI,> A is exact, then, if the
cycles stabilize in the spectral sequence (see section 9, Definition 1), then the left defect is zero, and therefore the inverse limi t abutments
I
Hn, n E 7",
are perfect in the sense of Defini-
tion 5. Remark 7.
In Remark 1 after Definition 5, under the hypotheses
of Theorem 2, we have a characterization of the left defect entirely in terms of
"V" ,
"t"
and inverse limits.
However, in
[O.A.L.), assuming additional very mild hypotheses on the given abelian category,
a (more complicated)
formula is given, in a
very different notation than ours, for the left defect in terms
The Partial Abutments . 1 .
of higher inverse limits (i.e., systems
depending only on
323
's) of certain lnverse
l~m
"V"
and
"tn.
Perhaps we should
note this here, somewhat generalized. Proposition 7.
([O.A.L.l, Theorem 2.2, pg. 18).
theses be as in Theorem 2 above. gory
A
Let the hypo-
Suppose that the abelian cate-
is such that denumerable direct products of objects
exist, and such that the functor "denumerable direct product": AW'V\,> A
is exact.
Then for every pair of integers
the inverse system
p,q
)
we have
p+i,q-i
r+l],q-l[preCiSe Pj,q l precise t + -;. rprec~se ~ -+- t-:-torsion . . . -; [ torsion in V -;. ••• ltorslon In V In V
1
i
(6
p,q,
This inverse system is a subsystem of the inverse system (6 ) n n = p+q.
of Theorem 2, Note 2, where p,q,
Also, for all integers
we have that the inverse system (6
of the inverse system (6
p,q
1
1) is a sub-system
p+ ,q-
).
Then, for every pair of integers natural isomorphism in the category (0)
p,q,
there is induced a
A, --;>
Ker [(liml ..... 0 l~
Notes: 1.
~i_] p+i ,q-i)_> (1. ml[prec~se [prec~se torslon In .to torslon V V l_
An equivalent statement is, that:
isomorphism of bigraded objects in
We have a natural
A,
"" 1· ~i_)P+i ,q-i (left defect) -;. (Ker( [lim (prec~se . · .... 0 torslon In l~
V
. l.m 1 (prec~se [ ·~o torslon l_
V
~ni+l-)P+il
q-i ))
J
(p,q)E7 x 7
324
Section 7
of bidegree equal to that of the mapk in the exact couple, i.e., in the notations of Theorem 2, Note 2, of bidegree l-r
(r
o
- a,
8).
O
2.
The proof shows in fact that the indicated isomorphism;
are induced by the mapping k in the exact couple, followed by a coboundary in an exact sequence of six terms of
liml.
I
The proof also computes the cokernel of the map of
3.
limIts
lim
induced by the inclusion
(6p+l,q_l)
->-
i>O
(6 p ,q)
as being
I
Ilml[«tiV) II (Ker t»Plq].
i>O Proof:
As noted in the statement of the Proposition, the inverse
system
(6p+l,q_l)
is a subsystem of (6
Plq i I th spot of the quotient inverse system is
(
).
The object in the
. se t i + l - t ors~on . ti-torslon)P+i ,q-i . )P+i Iq-i; ( prec~~e prec 7 ~
V
~n
~n
The mapping
V
induces an isomorphism from this latter object
onto
)
]
Plq
.
Therefore, we have the short exact sequence of inverse systems (1)
0-+ (6
p+-
1
1)'" (6
,q-
P,q
)
:ri.(I(preCiSe t-torsion)n in
V
(1m
)
p,q)
I
.. 0 •
i>O
The inverse limit of the rightmost inverse system is
(2)
[(precise t-torsion in
V) n (t-divisible part of
V)]p,q.
Also, the inverse limit of the middle term in (l} is lim (6
i~O
) p,g
=
lim [precise ti+1-torsion in V]p+i,q-i. i >0
The Partial Abutments The (infinitely t-divisible part of
325
V)p,q
is by definition the
image of the mapping [lim vP+i,q-i] .... vP,q. i>O It follows readily that (3)
[(precise t-torsion in
n
V)
(infinitely t-divisible part of
V)]p,q
is the image of the natural mapping, p:
' ( preclse ' t i + l -torslon "V)p+i,q-i] [1,lm In .... l>O [precise t-torsion in
V]p,q.
But the inverse limit of the rightmost mapping followed by the inclusion, is the mapping Im(lim TI) =Imp = the object (3). i>O (4)
p.
TI
in (1),
Therefore
That is,
[Im{lj;m TI)] "" [(precise t-torsion in i>O {infinitely t-divisible part of
V) n
V)]p,q.
Throwing the sh0rt exact sequence of inverse systems (1) through the cohomological, exact connected sequence of functors liml
lim,
of length two, we obtain, using the computation (2) of
Ij;m of the rightmost inverse system in (1) and using equation (4), that [(t-divisible part of V) n (I<er t) ]p,q [(infinitely t-divisiblE) n (Ker tJP,q part of V
Section 7
326 But, by Remark
I followinq Definition 5, we have that (left
defectl P- r O+ o ,q+r O+8-1 by
k,
is isomorphic, by the mapping induced Q.E.D.
to the left side of this equation.
Remark:
The preceding proposition can be used in the proof of
section 9, Theorem 4, below; but it is perhaps easier to prove that result directly, rather than using
liml
The Partial Abutments of the Spectral Sequence of an Exact Couple in
AD
Much of the results of this section can be generalized to exact couples in the D-graded category Definition 6. TED
Let
D
be an additive abelian group and let
be an element that is not an integer torsion element- i.e.
such that
n E if,
n >I
define the lines in il'T
AD.
= {n'
T:n Eil}.
of all lines in
D
n. T 'lOin
to be the cosets of
We will sometimes let D.
D. D
L
the y-intercept of the
YR.
of the line
~
Notice that the set
R.,
Then let us by the subgroup
stand for the set
Suppose that, for each line
we choose an element
Remark:
implies
R.
(!
L
that
which we shall call
R.. L
of all lines coincides with
I
The Partial Abutments the quotient group sum of two lines.
D/(~·
,).
Also, if
then we have the translate d.
Therefore, we can speak of the 9,
is a line and
9, + d
of the line
(This is simply the sum of the line
d + tZ . ,
in
Example. il x ~
D/
(~
9,
d ED 9,
is a degree,
by the degree
and the line
• ,) ) •
D=ilx~
If
327
and if
,=(-1,+1),
then the lines in ~
are the lines in the usual sense of slope -1 in
Therefore the lines in
il x il
are in natural one-to-one corres-
pondence with the integers, where to each integer ciate the line cept
y9,
9,n = { (p,q): p + q = n}.
of the line n
integers nology
9,
n
x Z.
n
we asso-
Let us take the y-inter-
to be the element
(O,n)E 9, ,
all
n
(The choice in this Example explains the termi-
n.
ny-intercept" in Definition 6 above).
The remainder of this section is parallel to, and more general than, definitionsand theorems given earlier in this section. Remark: if
A
Accordingly, we use a corresponding numbering. In general, if
D
is an additive abelian group, and
is an (ordinary, ungraded) abelian category, then we
have the abelian D-graded category section 3.
as in Example 1 of
In Example 2 of section 4, we have used the term
D-graded spectral sequence in
A
the abelian D-graded category
AD.
term
AD,
for a spectral sequence in Let us similarly use the
D-graded exact couple in the (ordinary, ungraded) abelian
category
A,
for any exact couple in the D-graded abelian cate-
gory Definition 3'.
Let
D
be an additive abelian group, let
,E D
be an element that is not an integer torsion element, and suppose that we have chosen a representative element
y 9, E 9"
(the
328
Section 7
ny-intercept"), for all lines Let
A
1 EL
as in Definition 6 above.
be an (ordinary, ungraded) abelian category.
Let
(1)
be a D-graded spectral sequence starting with the integer
rO
(as defined in Example 2 of section 4) in the (ordinary, ungraded) abelian category n
(Eoo)nED
Suppose also that
A.
E -term 00
are given short exact sequences:
exists, and that we
(2)
in the abelian category
A
for all degrees
nED.
(We call
such a set of short exact sequences (2) a partition of n
(Eoo)nED')
Then by a set of partial abutments for the D-graded
spectral sequence (1) with respect to the partition (2) of n
(Eoo)nED'
we mean a sequence
(3)
('H 1 , p,l "Hl" p,l)
(a)
'Hl
,
T
,
,
T
pEJ', 1 a line
where and
"Hl
category (b)
A,
are filtered objects in the abelian for all lines
1 Y +pT 'T P , : 'E 1 -+G p ('Hl) 00
abelian category lines
1,
A,
1 E L.
is an epimorphism in the
for all integers
p
and all
and is a monomorphism in the
(c)
abelian category lines Suppose that
1.
A,
for all integers
p
and all
The Partial Abutments
329
of partial abutments for the D-graded spectral sequence (1) with respect to the partition of (E~)nED
'H~,
~
(2).
Then we call
a line, the direct limit abutments, or the right abut-
"H~,
ments, and
~
a line, the inverse limit abutments, or
the left abutments. Theorem 2'.
(The partial abutments of the spectral sequence
of a D-graded exact couple.) Let of
0
0
be an additive abelian group, let
T
be an element
that is not an integer torsion element, and suppose that
we have chosen elements line
~
Let
E L
y~ E~,
the "y-intercepts", for every
as in Definition 6.
A be an (ordinary, ungraded) abelian category, and
let
(1)
be an arbitrary D-graded exact couple in the abelian category such that
n
deg ( (t ) nED)
into
for all
(2)
n dn n) (E r' r,T r nED r>O
=
T•
nED) •
(Thus,
is a map in A from
Let
be the spectral sequence of the exact couple (1). n
t = (t ) nED'
n
V = (V ) nED.
Let
Suppose that the (t-torsion part),
the (infinite t-torsion part), the (t-divisible part) and the (infinitely t-divisible part) of the D-graded object
Vall
exist, as defined in Definitions l' and 2' of section 5 (this
Section 7
330
condition is automatically satisfied if, for example, the abelian category
A
is closed under denumerable direct products
and denumerable direct sums of objects, see Example l' following Definition 2' of section 5). we have that:
Then, by Theorem 4' of section 5, n
The Eoo-term,
(Eoo)nED'
of the spectral sequence
(2) exists, and that we have the short exact sequence of 0graded objects in
o ...
(*)
A:
[(Ker t)
n (t-diviSible)] part of
vi (t-torsion) ] [toryl (t-torsion» where the maps
"h"
and
spectively by the maps
of "h"
"h",
and
"k"
are maps in
hand
("En) 00 nED
<:
«- 0,
"k"
passing to the subquotients.
v
k
If we let
natural isomorphisms in
"k"
induced re-
in the exact couple (1) by ('E~)nED
be the coimage of
is a monomorphism and
AD,
"k",
be the image then since
is an epimorphism, we have the
AD:
(*.1)
vI (t-torsion) ] ~ [ to(V/(t-torsion) ~
(*.2)
("En)
n ('E',)nED
and
00
nED
~[(Ker
induced by
hand
quotients.
(These isomorphisms are not, in general, of degree
zero.)
k
t) n (t-diviSible)] part of V
respectively, by passing to the sub-
And then we have the short exact sequencsin the abelian
category
A,
(*' )
all degrees
nED.
(*')
is a partition of
The Partial Abutments
331
sense of Definition 3' above, which we call the partition of n
(EoolnED
induced
£l the exact couple (ll.
Then there is induced a natural set of partial abutments: (3)
for the spectral sequence (2) with respect to the partition (*')
of For every
such that
dE D,
(p,~)
there exists a unique pair
d=y~+pT.
(Pd'~d)'
Call this pair
Eiflx L
Then, for the
associated graded of the direct limit abutments, we have the canonical isomorphism in G (Pd(
(4)
'H~d
AD,
~
»dED-
[
V/(infinite t-torsion) ] t'(V/(infinite t-torsionl)
and for the associated graded of the inverse limit abutments, we have the canonical isomorphism in (G
(5)
Pd
("H ~d»
dED
~>
AD,
(Ker t)n [(infinitelY t-divisiblel1 part of V •
We have that the direct limit abutment
'H~
is always co-
complete as filtered object in the abelian category that the inverse limit abutment
"H~
The degrees of the map
of the map
"h"
h
and
is always complete as
filtered object in the abelian category Note 1.
A,
A,
for all lines
~.
in the exact couple (1),
in the short exact sequence (*), of the canoni-
cal isomorphism (*.1) and of the canonical isomorphism (4) are all the same.
Let
cS
ED
Similarly, the map "k"
denote that degree. k
in the exact couple (1), the map
in the short exact sequence (*), the canonical isomorphism
332
Section 7
(*.2) and the canonical isomorphism (5) all have the same degree.
Let
Note 2.
K
denote that degree.
ED
51, ~
For every line
y -2T
~
> VY 5l,-T t
we have the infinite sequence
A,
in the abelian category t
L,
Y -T 51, >
Y
vy5l,~Vy5l,+T t
Y +T 51,
>v Y 5l,+2T t
Y +2T 51,
> •••
The objects that actually occur in this sequence are precisely those
v
d
such that
d
is on the line
51,.
Let
'K5I,
be the
direct limit of the sequence (651,)' 51,
(7.0)
'K
Y 5I,+PT = lim .... V p .... +oo
.
Introduce a filtration on
be defining
to be the
image of the natural map into the direct limit, (7.1)
for all integers
p.
Then we define the direct limit abutments
to be the filtered objects
'K5I"
with some shifting of degrees.
Explicitly,
(7.2) where
<5 =
deg h
and every line
(as in Note 1), and where for every degree 51"
a!(',d
denotes the unique integer such that in
Similarly, let
"K!(,
Y -pT
(8.0) "K5I, = lim V!(,
p .... +oo
d
D.
be the inverse limit of the sequence
•
The Partial Abutments Then introduce a filtration on
333
by defining
to be
the kernel of the natural map from the inverse limit, t (8.1)
F P "K
t = Ker ( "K
for all integers
p.
Yt-(p-l), ->- V
)
,
Then we define the inverse limit abutments
to be the filtered objects
t "K ,
with some shifting of degrees.
Explici tly,
is the integer defined by equation (7.2.1) above.
where Proof:
The proof of Theorem 2' is the same as that of Theorem
2 above.
Remark 1.
Definitions 4 and 5, Corollaries 2.1, 2.2 and 2.3,
and the Example following Corollary 2.3 all generalize immediately to the situation of Theorem 2'.
Similarly, Definition 1
generalizes to D-graded spectral sequences. Definition 1'.
Let
D,T,L,
and
Yt'
tEL,
Namely, be as in Defini-
tion 3', let
A be an (ordinary, ungraded) abelian category
and let
n n n (Er,dr,T r) nED
(1) =
be a D-graded spectral sequence
r.::ro in the (ordinary, ungraded) abelian category
A.
Then an abut-
ment for the D-graded spectral sequence (1) is a sequence (8
t
,T
p, t)
E
where
HQ,
is a filtered object in the abelian category
P 6' tEL (1)
for all lines (2)
(E~) nED
t,
A,
such that
exists as defined in section 4, Definition
4 '; and where t y +PT
(3)
TP
,
:
E t 00
":;. G (Ht)
P
is an isomorphism in the cate-
334
Section 7 gory 9,
A,
pE~
for all integers
and all lines
E L.
Then, also, the Remark following Definition 1; Definition (The generalization of Definition 2.1 has
2; Definition 2.1
to be carefully phrased. D
It defines an additive D-graded cate•
(A), such that the objects are all rO D-graded spectral sequences with abutments in the (ordinary,
gory, Spec. Seq. Abut.
A); Theorem 1; Remarks 1 and 2
ungraded) abelian category
(and the material following) after Theorem I: Corollary 1.1 and Remarks 1 and 2 following Corollary 1.1; all generalize to the situation of Definition l' above. And also, Remark 3 following Corollary 2.3; Thm. 3 and the assoc. Example; Cor. 3.1 and the assoc. Example; Proposition
4;
the Remark following Proposition
4;
Proposition 5; Corollary
5.1; Remarks 1 and 2 following Corollary 5.1; Proposition 6; Corollary 6.1; Remark 3 following Corollary 6.1
(In the gener-
alization of Remark 3 following Corollary 6.1, the indexing has to be done carefully, as in Note 2 to Theorem 2'); and Remark 4 following Corollary 6.1; Rks. 6 and 7; Prop. 7; and Rks. 1 and 2 after Defn. 5; then all generalize to the situation of Thm. 2'. Remark 1.
Let
D
be an additive abelian group, let
A be an
(ordinary, ungraded) abelian category and let
V
t
>V
~/"
(1)
E
be an arbitrary D-graded exact couple in the (ordinary, ungraded) abelian category
A.
(That is,
(1) is an exact couple in the
The Partial Abutments abelian D-graded category
AD).
335
Then when do the considera-
tions of Definition 3' and of Theorem 2' above hold?
,= deg (t),
In Definition 3' and in Theorem 2', if we must have that additive group
,
is not an integer torsion element of the What if the element
D.
then
integer torsion element?
,= deg (t)
ED
is an
Then is there still a way to make use
of Definition 3' and of the results of Theorem 2'?
The answer
is "yes". Namely, let ¢ :DO
->-
that E
D
DO
be an additive abelian group and let
be an epimorphism of additive abelian groups, such
Ker ¢ is not entirely integer torsion.
are objects, and
category n
h = (h )nED' K=deg(k),
t,h
and
we have that
k
V
and
are maps, in the D-graded
n V = (V )nED'
n
E = (E )nED'
n
t = (t )nED'
n
o=deg(h) and k = (k ) nED I f ,=deg(t), n n n then t (resp.: hn,k ) are maps from V (resp. :
Choose an element
into
into such that
ger torsion element and such that since by hypothesis
Ker(¢)
¢(00) =0, ¢(K ) =K. O
'0
¢ h 0) = ,
(resp.:
Vn + K). is not an inte(this is possible
has at least one element that is
not an integer torsion element), and let that
Since
0 , K0 E DO 0
Then define
Then and are objects in the Do-graded category
Define
be such
336
Section 7
degree t
TO'
o
resp.:
= (t¢ (m),
= (h¢ (m))
h
'!nED'
mED O'
o
o
Then we have the Do-graded exact couple in the (ordinary, ungraded) abelian category
A
is, by construction, not an integer torsion element of the additive abelian group (2)
DO.
Let
(E~,d~,T~)nED r>O
be the spectral sequence of the D-graded exact couple (1).
Then
(2) is a D-graded spectral sequence in the abelian category For each degree
all integers
r > O.
m E DO'
A.
define
Then
is a Do-graded spectral sequence in the abelian category It is easy to see that (2 ) 0
A.
is the spectral sequence of the
Do-graded exact couple (2 ). 0 Since the degree
TO = deg (to)
of
to
is by construction
not an integer torsion element, Definition 3' applies.
There-
The Partial Abutments fo:rewe can choose DO'
"y-intercepts"
with respect to
TO'
337
y 9. E 9. for every line
as in Definition 3'.
J1.
in
Then by Theo-
rem 2' we have the partial abutments of the Do-graded spectral sequence (2 ) in the (ordinary, ungraded) abelian category 0
A.
In this way, Definition 3' and Theorem 2' can be applied to every D-graded exact couple in every (ordinary, ungraded)
A,
abelian category replacing
with
DO
and
torsion element of
DO
as above.)
Remark 2.
D
for every additive abelian group T
with
TO
D.
(By
that is not an integer
The construction of Remark 1 above is related to
that of Exercise 4 ("change of grading group, other direction") following Corollary 5.1 of section 3. Example.
Let
A
be an (ordinary, ungraded) abelian category,
and let
(1)
be a conventional singly graded spectral sequence in the (ordinary, ungraded) abelian category
A.
Then, by definition of a
"conventional singly graded spectral sequence", see section 4, Example 3, we have that n
deg ( (t ) nE?) = O. Therefore, Definition 3' and Theorem 2' cannot be applied to the exact couple (1) without using the technique of Remark 1 above.
338
Section 7 Let
CP::?l xZ-+Z
TO = (-l,+l)EZ xZ.
be the sum map, If
CP(p,q) =p+q.
n
Let
n
and S = deg(k )~Z'
a = deg (h ) nE Z
then, by definition of a "conventional singly graded spectral sequence", we must have that a+S=+l Define
a
O
=
(O,a)
in
:?l.
and
So
= (O,S)
tion of Remark 1 above applies.
in
:?l x:?l.
Then the construc-
The exact couple
associated to (1) by the construction of Remark 1, is a conventional bigraded exact couple starting with the integer
0.
Also,
if (20) is the conventional bigraded spectral sequence starting with the integer zero associated to the exact couple (10)' and if (2) is the conventional singly graded spectral sequence associated to the exact couple (1), then it is easy to see that the bigraded spectral sequence (20) comes from the singly graded spectral sequence (10) by the construction of Remark 2 following Example 5 of section 4. Therefore, in this way the results of Definition 3 and of Theorem 2 can be applied to any conventional singly graded exact couple (1) in any abelian category
A-or, more precisely, to
the associated conventional bigraded exact couple (1°) starting with the integer zero constructed in Remark 1 above.
Section 8 The Spectral Sequence of a Filtered Cochain Complex
Let
A
be an abelian category and let
cochain complex in
A.
Suppose that we
ha~e
C*
p,
such that
FpC*::::l Fp+1C*,
Thus, equivalently, in the abelian category for each integer
n,
and for all integers
n
such that F p+l C n n n+l , d (F C ) C F C p
n d +l
0
p
d
n
= 0,
C
an object nand
a subobject
p
F p C* ,
all integers
n C
(7-indexed)
a filtration on
C*--that is, that we have subcochain complexes tegers
be a
and a map
all in-
p. (*) A,
we have,
dn:C n
->
cn + l
;
of
n
FpC, for all integers p,n; such that . all ~ntegers p,n; and such that
all integers
n.
We will call such a collection
of data a filtered cochain complex in the abelian category
(Spectral Sequence of a Filtered Cochain Complex).
Theorem 1. Let
(F p C*)pE7
category
A.
A.
be a filtered cochain complex in the abelian Then there is induced a conventional, bigraded
spectral sequence starting with the integer 1 such that
(*)An equivalent way of formulating this data is: "Suppose that we have a filtered object in the abelian category CoCA)". (.Another equivalent formulation is: "Suppose that we have a w-indexed) cochain complex in the additive category Filt(A) of all filtered objects in the abelian category A." 339
340
Section 8
This spectral sequence comes from a conventional, bigraded exact couple starting with the integer one,
(2)
A,
in the abelian category
in which
EP,q=HP+q(G p «C*» , tp,q
HP+q(inclusion:
=
C*) hP,q = HP +q (natural epip-l' kP,q = the (p+q) 'th coboundary in the
F C*
F
+
p
morphism: Fp C* .... Gp C*) and cohomology sequence of the short exact sequence (3), vide infra. In particular, the bidegrees of h
(hP,q) (p,q)E.lx.l
and (+1,0) Proof:
and
k
=
t
= (tp,q)
(p,q)EzxZ'
(kP,q) (p,q)E.lxz
are (-1,+1), (0,0)
respectively.
For every integer
P,
we have the short exact sequence
A,
of (.l-indexed) co chain complexes in the abelian category (3)
A+ Fp+lC* inclusion>F PC*
natural> G C* epimorphism p
+
0
,
which yields the long exact sequence of cohomology n-l
(4)
2--> Hn (F pH C* ) n
H (G C*)
P
d
n
-=--!>•••
n n H (inclusion» Hn (F C*) H (natural p epimorphism)
Filtered Cochain Complex
341
statement of the Theorem, then we obtain the conventional bigraded exact couple (2) starting with the integer 1.
Then let
(1) be the conventional, bigraded spectral sequence starting with the integer 1 of the exact couple (2), using the indexing convention given in Example 3.1 of the end of section 5. Q.E.D. The following diagram may aid in visualizing the exact couple of Theorem 1.
In this diagram, Corollary 1.1.
n = p+q
throughout.
The hypotheses being as in Theorem 1, suppose
in addition that the abelian category
A
has denumerable di-
rect products of objects and denumerable direct sums of objects. Then the spectral sequence (1) of Theorem 1 comes equipped with a set of partial abutments.
The direct limit abutments are
'Hn=limHn(F C*) -+ -p' p-++oo
(5)
and the inverse limit abutments are n "H = lim Hn + l (F C*) ofp' p-++oo
(6)
all integers Proof:
n.
Follows immediately from Theorem 1 and from section 7,
Theorem 2. Corollary 1.2.
The hypotheses being as in Corollary 1.1,
342
Section 8
suppose in addition that the functor, "denumerable direct product":
AW'VV> A n C
objects
is exact.
are complete, for all integers
verse limit abutments Note:
Suppose also that the filtered
"H
n
n.
Then the in-
are zero, for all integers
The proof shows, more generally, that if
n
Cn
n c -l
cular integer, such that
is Hausdorff and
n.
is a partiis "com-
plete but not Hausdorff" as filtered objects, then the (n-l) 1st n l "H -
inverse limit abutment Proof:
By Chapter
3
is zero.
of the main text of this book below,
Proposi tion 1, and the N:> te following, if we define for all integers n
objects
An
i, in
C!
=
F i C* ,
then there are induced for each integer A,
and short exact sequences,
(2)
and a long exact sequence (3)
is Hausdorff, then
lim cr: = n c~ = o. i>O 1 i>O
If
is "complete but not Hausdorff", then by section 6, Corollary 7.1,
(and the Remark immediately following), we have that
l l' ,l:.m1 Cr:- = O.
1> O
1
Therefore
Hn (lim C'l<) = Hn - l (liml C~) = O. i>O 1 i>O 1
from the long exact sequence (3), we have tha t
An = O.
fore, from the short exact sequence (2), we have that
Then There-
Filtered Cochain Complex
343
or, changing notations back, that n
l~m H (F C*)
p-,+oo
P
=
o.
Comparing with equation (6) of Corollary 1.1 gives the result. Q.E.D. Corollary 1.2.1.
Under the hypotheses of Corollary 1.2, we
have also that
for all integers Note:
n.
If the hypotheses are as in the Note to Corollaryl.2,
then the proof of this Corollary shows that
for the particular integer Proof:
n.
Proceedings as in the proof of Corollary 1.2, the proof
showed that
An =
o.
Equation (2) in the proof of Corollary 1. 2
therefore completes the proof. Remark.
Q.E.D.
In the Introduction to an earlier unpublished version
of the paper [O.A.L.], Laudal poses the problem:
Given a con-
ventional bigraded exact couple in an abelian category, such that denumerable direct products and denumerable direct sums exist, and such that the functors, "denumerable direct product" and "denumerable direct sum" from
AW into
A are both exact;
then does it follow that there necessarily exists some decreasing filtration on
344
Section 8
liml Vp,n-p p++ro such that the associated graded is isomorphic to the bigraded object, the left defect, as defined in section 7, Definition 5?
The answer to this question is "No".
(F p C*) p E""
In fact, let
be any filtered cochain complex of abelian groups
(I.
such that the left defect of the spectral sequence (1) of Theorem 1 is non-zero. section).
(We give such Examples at the end of this
Then, as shown in Corollary 2.1 below, the left
defect of the spectral sequence of
C*
is isomorphic to the
left defect of the spectral sequence of the completion C*.
of
If we consider the exact couple of the filtered cochain
complex
1,
C*A
C*A as in Theorem 1, then by equation (2) of Theorem
VP,q=HP+q(F (C*». p
Therefore
and this latter is zero by Corollary 1.2.1.
Therefore, given
any complete filtered cochain complex with left defectizero, it is a counterexample to the problem of Lauda1 (since the associated graded of any filtration on
liml Vp,n-p + p++ro
is zero, yet the
left defect is not zero). Corollary 1.3.
The hypotheses being as in Corollary 1.1, if in
the abelian category
A we have that the functor "denumerable
direct limit" is exact, then the direct limit abutments are perfect in the sense of section 7, Definition 5, and moreover (7) Proof:
n n 'H = H (co-completion C*),
all integers
If denumerable direct limit is exact in
A,
n. then by
Filtered Cochain Complex
345
section 7, Corollary 2.3, the direct limit abutments perfect, all integers "4m"
n.
in equation (5),
Moreover
n "H "
are
commutes with
giving equation (7).
Q.E.D.
p++oo
The next corollary is rather special (in comparison to the preceding two), but is often useful. Corollary 1.4.
The hypotheses being as in Theorem 1, suppose
that the abelian category
A
is such that denumerable direct
sums of objects exist, and such that denumerable direct limit is exact.
Suppose also that the filtered cochain complex
(F p C*)pE7.
is such that, for each integer
n
object
(FpC )pE7.
n,
the filtered
is discrete.
Then the direct limit abutments,
I
n H ,
n E 7. ,
defined by
equation (5) of Corollary 1.1, obey equation (7) of Corollary 1. 3, and
are an abutment for the conventional bigraded spectral
sequence (1).
Moreover, this abutment is discrete and co-com-
plete. Proof: teger
By hypothesis, p' = p' (n),
~or
each integer
depending on
then for all integers
p
~
pI
F ,C
n
p
we have likewise that
stated, for the fixed integer such that
there exists an in-
such that
for all integers
Therefore
p' = p' (n)
n,
n
Vp,n-p = 0
n,
P ~p'.
=
o.
But
F Cn=O. p
Otherwise
there exists an integer whenever
p ~pl (n).
Therefore
the hypotheses of section 7, Proposition 4, part (2), hold. Q.E.D. Remark 1. A
Of course, by Corollary 1.2, if the abelian category
obeys all the hypotheses of Corollary 1.4, and if the fil-
tered objects
n C
are complete, for all integers
n,
then
Section 8
346
necessary and sufficient conditions for the direct limit abutments to be an abutment (in the sense of section 7, Definition 1), is that the inverse limit defect be zero.
That is not
always true under these hypotheses, not even if
A is the cate-
gory of abelian groups, as we shall see by an example below. Remark 2.
Of course, many more observations can be made in the
situation of Theorem 1.
For example, section 7, Theorem 3, gives
necessary and sufficient conditions for the direct limit abutments to be an honest abutment in the sense of section 7, Definition 1; similarly for section 7, Corollary 3.1, and the inBy section 7, Theorem 2, the direct
verse limit abutments.
limit abutments are always
co~omplete.
Section 7, Proposition
5, gives necessary and sufficient conditions for the direct limit abutments to be complete.
Section 7, Proposition 6
necessary and sufficient conditions for the direct limit abutments to be co-discrete; and section 7, the Remark following Proposition 4, gives necessary and sufficient conditions for the direct limit abutments to be discrete.
Similar conditions
for the inverse limit abutments can be given. Let
A
be an abelian category, and let
C* = (F (C*)) p
A.
be a filtered cochain complex in the abelian category
,,~
P'"4'
Then
by Theorem 1, we have the conventional bigraded spectral sequence (1) starting with the integer 1, which we shall call the spectral sequence of the filtered cochain complex (FpC*)pE~.
=
Under the hypotheses of Corollary 1.1, we shall call
the partial abutments
'Hn, "H
filtered cochain complex of
C*
(E~,q) (p,q)E~x~
n
the partial abutments of the
C* = (F C*) P pE~·
The induced partition
will be called the partition of
Filtered Cochain Complex (EP,q)
(p, q)
00
E7! x:r
347
of the filtered cochain complex
-
C * = (FpC * ) pE:r • Remark 1. completion exists
Under the hypotheses of Theorem 1, suppose that the C*A of the filtered cochain complex
(F C*) P pE:r (a condition that is automatically satisfied if, e.g.,
the abelian category products).
C*
=
A is closed under denumerable direct
Then we have a map:
of filtered cochain complexes, which induces a map:
of the associated exact couples, where (2A) denotes the exact couple of the filtered cochain complex
C*A.
By section 6,
Corollary 4.1, the natural mapping of filtered cochain complexes induces an isomorphism on the associated gradeds,and therefore,
EP,q 1 •
by Theorem 1, on 4', the mapping
6
Therefore, by section 4, Proposition
of exact couples induces an isomorphism on
the associated spectral sequences. chain complexes
C*
tral sequences.
The exact couple
~
called ~
and
C*A
Therefore, the filtered co-
have canonically isomorphic specA
(2),
when defined, will be
exact couple of the completion of the filtered co-
C* = (F C*) • Similarly, the partial abutments P pE:r A of (2 ), when defined, will be called the partial abutments of complex
the completion of the filtered cochain complex
C*.
However, it is not difficult to see by examples (see the Examples at the end of this section) that in general the exact couples
(2) and (2A) have different direct and inverse limit
348
Section 8
abutments, and also in general induce different partitions of
(E~,q)
(p,q) E'J'x'l'.
Remark 2.
The hypotheses being as in Theorem 1, suppose that
co-comp(C*) exists.
Then we have a natural mapping:
co-comp (C*) .... C* that induces a mapping on the associated exact couples. ever, by Theorem 1, we have that HP+q(G C*) p
for all integers
How-
vp,q = HP +q (F p C*) ,
p,q
in the exact couple (2).
By the dual of section 6, Corollary 1.2, conclusion (3), we have that the natural map: F (co-comp C*) .... F C* P P is an isomorphism of cochain complexes, for all integers
p.
Similarly, by the dual of section 6, Corollary 4.1, the natural map: G (co-comp C*) .... G (C*)
p
p
is an isomorphism, for all integers
p.
It follows that the
natural mapping of filtered cochain complexes: co-comp (C*) .... C* induces an isomorphism, not merely on the associated spectral sequences, but even on the exact couples. cochain complexes, co-comp(C*)
and
C*,
That is, the filtered have canonically iso-
morphic exact couples, and therefore also canonically isomorphic: spectral sequences; partial abutments tions of
E •
00'
(if they exist): parti-
direct and inverse defects; etc.
Filtered Cochain Complex Remark 3.
349
Suppose, under the hypotheses of Theorem 1, that the
filtered cochain complex co-comp(C*)
C*
=
(F C*) p pE2'
1'1
and co-comp(C* )
all exist.
is such that
c*1'I ,
(A condition that is
automatically satisfied if, e.g., the abelian category
A
is
such that denumerable direct products and denumerable direct sums exist).
Then the construction of Theorem 1 applies, to
yield, at first glance,
~
distinct exact couples, namely the
exact couples of the filtered cochain complexes co-comp(C*)
and co-comp(C*I'I).
By Rk. 2,
C*
C*, c*l'I,
and co-comp(C*)
have the same exact couple; similarly C*I'I and co-comp(c*l'I) have the same exact couple. Therefore, these four filtered cochain complexes yield only two in general different exact couples, namely, the exact couple (2) of of the cochain complex
C*
1'1
and the exact couple (2 )
c*l'I.
The exact couple (2) constructed in Theorem 1 is not selfdual, although the spectral sequence (1) of that exact couple is self-dual. Theorem 10.
More precisely, (Dual Exact Couple of the Spectral Sequence of a
Filtered Cochain Complex). 1.
Let the hypotheses be as in Theorem
Then there is induced a conventional, bigraded exact couple
starting with the integer one,
in the abelian category
A,
in which
350
Section 8
°vp,q
=
HP + q (C*/F
°EP,q
=
HP +q (G C*),
°tp,q
=
HP + q (natural epimorphism:
°hP,q
=
the (p+q+l) 'st coboundary of the short exact sequenc
°kP,q
=
HP +q (inclusion:
p+l
C*)
'
P
G C* p
In particular, the bidegrees of h = (hP,q) (p,q)EZ'xZ' ~1,0)
and
->
C*/F
C*/F
p+l
p+l
C*-+C*/FC*) p'
C*).
t = (tp,q) (p,q)Ei!xi!'
k = (kP,q) (p,q)EZ'xZ'
are (-1,+1),
and (0,0) respectively.
The spectral sequence of the exact couple (2
0
)
coincides
with the spectral sequence (1) of the exact couple (2) of Theorem 1. Note:
The proof of Theorem 1
0
also constructs an explicit map
(g,f) of bidegree (0,0) of conventional bigraded exact couples starting with the integer one, from the exact couple (2 0
)
into
the exact couple (2) of Theorem 1, such that the indicated map induces the identity mapping on the associated spectral sequencee Remark:
Although the exact couples (2) of Theorem 1 and (2 0
)
of this Theorem have the identical spectral sequence (1) of Theorem 1, nevertheless as we shall see later, they are in general very different exact couples. Proof:
For each integer
of cochain complexes in 0-+ G C* -+ C*/F C* P p+l
p
we have the short exact sequence
A ->
C*/F C* -> 0 p'
which yields the long exact sequence of cohomology
Filtered Cochain Complex n- l
Hn(,
1
'
351
)
d --~ Hn (G C* )~nc US1.on ~Hn (C* IF C*) P p+l
n
H (natural ~ epimorphism)
n
Hn(C*/F c*)_d __ >
p
The rest of the construction of the exact couple (2°) is similar to (and dual to) that of Theorem 1. Let
n
respectively:
d(3) ,
denote the n'th co-
boundary in the cohomology sequence of the short exact sequence of cochain complexes this Theorem.
(3) of Theorem 1, respectively:
Let
denote the n'th coboundary in the
short exact sequence of cochain complexes
o . ,. F
C* ..,. C* ..,. C* IF C*..,. O.
P
P
Then we have the commutative diagram with exact rows, (6 )
•••
(The upper row in (6) is the long exact sequence (4) of the Proof of Theorem 1; the bottom row is the long exact sequence (4
0
)
of this Theorem.)
Commutativity of the displayed three
squares, from left to right, follows, respectively, from naturality of the coboundary, with respect to the map of short exact sequences:
from (3) of Theorem 1 into (5 + ); respectively p l
from (5 + ) into (5 ); respectively from (5 ) into (3°). p l p p
There-
fore, it we define gP,q = d P +q
(pH)
then
and
fP,q
g = (gP,q) (p,q)E7Q'
=
identity of respectively:
HP +
q (G C*) P
,
f = (fP,q) (p,q)E;rq'
Section 8
352
°v -_
is a map of bigraded objects from V = (Vp,q) (p,q)Ezq' into
E = (EP,q)
respectively:
(p,q)E~XJl:
(0 p, q )
V
from
(p,q)E~x~
°E - (oEP,q) -
. t 1n
(p,q)~·x~
of
of bidegree (1,0), respectively:
'
0
bidegree (0,0); and the pair (g,f) is a map of exact couples, as defined in section 5, Definition 5', in the bigraded abelian category
A~x~,
Corollary 5.0.1.
of bidegree
(0,0) in the sense of section 5,
Therefore, by section 5, Proposition 6, we
have an induced map of spectral sequences of bidegree (0,0) from the spectral sequence of the exact couple (2 spectral sequence of the exact couple (2). identity of
°EP,q=EP,q,
sequences is the identity phism.
Since
0
into the
)
fP,q
is the
it follows that this map of spectral 0
and is therefore an isomor-
n
Therefore by section 4, Proposition 4', with
r 0 = 1,
it follows that this map of spectral sequences must be an isomorphism of spectral sequences.
Finally, by section 4, Remark
l' following Proposition 0.3 (after Definition 51), this map of spectral sequences, along the
E~,q,s,
to the subquotients along the map of of
fP,q
is
is induced by passing El,q,s.
Since the map
which is the identity, all integers
p,g,
it follows that this map of spectral sequences must be the identity map. Remarks.
1.
Q.E.D. Under the hypotheses of Theorem 1, the filtered
complex
C*= (F C*) in the abelian category A deP pE.:?i' fines a filtered cochain complex in the dual category AO, which
cochain
we might denote plex.
°c*
and call the dual filtered cochain com-
Explitictly, the n-cochains in the dual filtered cochain
complex are tered piece
on -n C =C ,
for all integers n. And the pi th filo on of C is the subobect in A , that is
353
Filtered Cochain Complex the quotient-object in integers
n,p.
A,
for all
With this definition of the "dual filtered co-
chain complex;. we have of course that the dual of the dual of C*
is
C*,
°C* = C*,
for all filtered cochain complexes
Of course, the exact couple (2°) of Theorem 1°
C*.
is identical
to the exact couple of Theorem 1 applied to this dual filtered cochain complex
8*
in the dual category
AO, with a few minor
notational changes (the most notable notational shift is an interchange of the letters
"h"
and
"k"
for convenience; the
other notational shift is are-indexing). 2.
As in the case of the exact couple of Theorem 1,
a diagram of the exact couple (2 category
0
)
of Theorem 1
0
in the abelian
A may aid in visualizing this exact couple: Hn (
(Hn(C*/Fp+lC*))
natural
(epimorphism)~p,q)E~X~
(p,q)E~x~
) (Hn(C*/FpC*)) (p-l,q+l) Eil'xil'
n (H (inclusion) ) (p,q) E7Lq
In this diagram,
n = p+q
n (d ) (p-l,q +1) E6'xil'
throughout.
By duality, the corollaries to Theorem 1 each imply analogous corollaries to Theorem 1°.
We record a few of these,
correspondingly numbered. Corollary 1.1°.
The hypotheses being as in Theorem 1°, suppose
in addition that the abelian category
A has denumerable direct
products of objects and denumerable direct sums of objects. Then the spectral sequence (1) of the filtered cochain complex
354 C*
Section 8 comes equipped with a set of partial
abutment~
which we
will call the dual partial abutments, and which we denote
°
'''H n ,
n E £.
,~n,
The dual inverse limit abutments are
,,~n
n
= lim H (C* /F C*) p~+oo p
and the dual direct limit abutments are
°
(6)
on = l,l;m . Hn- 1 (C*/F 'H p ... +oo
-p
C*). (E P,q)
We will call the induced partition of
00
(EP,q)
dual partition of
00
°
Corollary 1.2 •
n C
The hypotheses being as in Corollary 1.1°,
is exact.
"denumerable direct sum":
Suppose also that the filtered objects
are co-complete, for all integers
limit abutments ~:
the
(p,q) EZXl','
suppose in crldition that the functor
AW~>A
(p,q) EZx.?
°
'H
n
n.
Then the dual direct
are zero, for all integers
n.
The proof shows, more generally, that if
cular integer, such that
n C
n
is co-Hausdorff and
is a partiCn + l
is
"co-complete but not co-Hausdorff" as filtered objects, then the (n+l) 'st dual direct limit abutment Corollary 1.2.1°.
,~n+l
is zero.
Under the hypotheses of Corollary 1.2°, we
have also that
for all integers Note:
n.
If the hypotheses are as in the Note to Corollary 1.2°,
then the proof of this Corollary shows that
355
Filtered Cochain Complex for the particular
n.
Proofs of Corollaries 1.1°, 1.2° and 1.2.1°:
Follow immediately
from Corollaries 1.1, 1.2 and 1.2.1 respectively applied to the dual exact couple (2°)
(which is the exact couple of the dual
filtered cochain complex Remark.
°
C*
in
AO)
in the dual category AO.
Of course, Corollaries 1.3 and 1.4, and Remarks 1 and
2 following Corollary 1.4, have similar dual statements which follow immediately by duality. For later use, we record a Lemma. Lemma 2.1.
Let
(g,f)
denote the map of exact couples de-
scribed in the Note to Theorem 1°. (8)
g -1 (1m t s )
(9)
°v
s
= 1m (( °t) s ).
Also, if the t-divisible part of ible part of
Then for all integers
V
exists, then the
°t-divis-
exists, and in fact
g-l(t-divisible part of
V) = (Ot-divisible part of °V).
(10) for all integers
n,P.
And, if the abelian category
A
is
closed under denumerable direct products and is such that the functor, "denumerable direct product", is exact, then (11)
g-l(infinitely t-divisible part of (infinitely
For all integers
°t-divisible part of
s,
And, if the t-torsion part of
V
exists,
V)
=
°V).
356
Section 8 (13)
(t-torsion part of
V)
C
1m g.
Also, we always have that (14)
9 -1 (Ker t) = Ker(°t) + Ker (g) •
We first prove equations (8), (10), (12) and (14).
Proof:
the Exact Imbedding Theorem,
By
([I.A.C.]) it suffices to prove
these equations in the case that the abelian category
A
is
the category of abelian groups. The commutative diagram with exact rows
(6) can be re-
written as (6' )
To prove equation (8), we must show that if gP,q(x) Elm(t s ) then
iff
s gP,q(x) E Im(t ).
gP,q(x) E Im(t s ) tion on
s.
Case 1.
s = 1.
then
Then
of the top row in
xElm«Ot)s).
x ECVP,q,
Clearly, if
then
xElm«Ot)s),
Therefore, it suffices to show that, if xE Im«Ot)s).
This is proved by induc-
gP,q (x) E 1m (t).
Therefore by exactness
(6 ' ), °hP +1, q(gP,q (x»
=
tive diagram(6'), it follows that °hP,q(x)
o. =
O.
From the commutaTherefore
x E 1m (Ot) •
Case 2.
s > 2.
have that x E Im(Ot),
Then since
gP,q (x) E Im(t). say
x = (Ot) (y),
gP,q(x) E Im(t s ),
a fortiori we
Therefore by Case 1, we have that where
y E vP+l,q-l.
Filtered Cochain Complex Then since of (6')
gP,q(Ot(y»
=gP,q(x)
we have that
Im(t s ),
t(gP+l,q-l(y»
from commutativity
=ts(z), there exists some
( p+l,q-l s-l tg (y)-t (z»=O, so by exactness of the top row of (6'), there exists eEE P + l ,q-l such that zEV
P+s+l q-s ' •
E=
357
Then
kP+1,q-l(e)=gP+l,q-l(y)_tS-1(z).
°vp + l
,q-l,
But then
(Ot) (y') = (Ot) (y) _ 0 = x,
gP+l,q-l(YJ_kP+l,q-l(e)=ts-l(z).
and
Y'=y_ Ok P + 1 ,q-l(e) E gP+l,q-l (y') =
Therefore gP+l,q-l(Y')Elm(t S - 1 ).
s y' = (Ot - l ) (x )' there exists o (Ot) s (x ) = (OtX (Ot s - l ) (x »
By the inductive assumption, E v P + s ,q-s xo· (Ot) (y') =x,
But then so that
0
xE Im(Ot)s,
That proves equation (8).
0
as required.
To prove equation (lO),notice
that under the identification of the diagrams (6) and (6'), we Since
is the n'th coboundary
in the cohomology sequence of the short exact sequence of cochain complexes (5 ), it follows that p
which proves equation (10). (12')
Also, it follows likewise that
Im(gP-l,n-p+l) =rm(d n( » = Ker(H n + 1 (F C*) +Hn+l(C*». p p .
The (p,n+l-p)'th component of the map is
n l H + (inclusion:
F C* p
-+
(p,n+l-p)'th component of ' Hn+l (.lonc l uSloon:
F C*
of equation (12'). compon'ent of being
P
-+
F t
C*) •
C*).
S
of bigraded objects
Therefore the kernel of the
is contained in the kernel of
But this latter is the right side
Therefore by equation (12') the (p,n+l-p)'th
Ker t S
is contained in
true for all integers
Equation
p-s S
t
n,p,
rro(gP-l,n- p +l). This
we obtain equation (12).
(14) is easily proved by diagram chasing.
358
Section 8
This proves equations (8), (10, (12) and (14). prove equations
(9),(11) and (13).
equation (8), for all integers
s
It remains to
Equation (9) follows from
~
1, and from section 2, part
(1) of the Lemma, just preceding Theorem 3 following Definition
5. Next, let us prove equation (11). °t-divisible part of V).
Clearly,
(infinitely
°V)cg-l(infinitely t-divisible part of
Therefore it suffices to prove that
(11')
g-l(infinitely t-divisible part of
V)c
(infinitely °t-divisible part of Let
C*/\
C*.
Then the exact couples (2
denote the completion of the filtered cochain complex 0
of
)
identical.
While the exact couples
C*
C*"
and to
natural map
C*
denote (2) for
C*
and of
-+
C*'\
induces a map, call it
C*I\
C*
,
into (2)
let
..j\
for
denote
constructed in the Note to Theorem 1 C*/\.
are
(2) of Theorem 1 applied to
Then
log = g/\ •
0
of exact
1 ,
C*'\ •
Let
(2/\)
for
C*I\
and let
V
denote the map of exact couples from
complex
C*'\
are not in general identical, nevertheless the
couples from (2) for
(f ,g/\)
°V).
(2°) into
(2/\)
for the filtered cochain
Therefore, to prove (11') it
suffices to prove that (11'/\)
(g/\)-l(infinitely t/\-divisible part of
(~nfinitely °t-divisible part of That is, replacing
C*
by its completion
c*/\,
vA)c °V). it suffices to
prove equation (11') in the case that the filtered cochain complex
C*
is complete.
But then
Filtered Cochain Complex lim Vp,n-p = lim Hn(F C*) = "Hn - l , p':f-oo p':+oo P zero by Corollary 1.2. of
V) = O.
359
and this latter is
Therefore (infinitely t-divisible part
Therefore, to prove equation (11), it suffices to
prove that (II")
Ker gc (infinitely °t-divisible part of
But, by definition of "infinitely
°V).
°t-divisible part", we
have that (infinitely
°t-divisible part of
This latter clearly contains
=
n H (C* IF f*) 1. But by p+ Ker(gP,n- p ). Therefore
n 1m [H (C*)
equation (10), the last group is (infinitley
°V)p,n-q
->-
°V)~
°t-divisible part of
Ker g,
proving equa-
tion (11"), and therefore completing the proof of equation (11). Finally, it remains to prove equation (13). (t-torsion part of subobjects of
V,
V)
is by definition the supremum of the s
Ker (t ),
for
s > 1.
Therefore equation (13)
follows from equation (12). Theorem 2.
Q.E.D.
Let the hypotheses be as in Theorem 1.
addition that the
In fact, the
abeli~n
category
able direct products (respectively:
A
is closed under denumer-
denumerable direct sums)
and that the functor "denumerable direct product": "denumerable direct sum":)
Suppose in
AW'VU> A is exact.
(respectively:
Then the natural
mapping frQm the exact couple (2°) of Theorem 1° into the exact couple (2) of Theorem 1 induces an isomorphism on the left de-
360
Section 8
fects (respectively: Proof: 9
on the right defects).
Equations (9) and (11) of the previous Lemma imply that
induces a monomorphism from (Ot-divisible part of °V) (infinitely Ot-divisible part of (t-divisible part of V) (infinitely t-divisible part of
into
OV)
V).
Comparing with the isomorphism in section 7, Remark 1 following Definition 5, it follows that
g
induces a monomorphism from
the left defect of the exact couple (2 0 of the exact couple (2).
into the left defect
)
On the other hand, by equation (12)
of the preceding Lemma with
s=l,
we have that
Ker tc 1m g. Therefore (15)
(Ker t)
n
(t-divisible part of
V) c 1m g.
Fix an exact imbedding from some exact full subcategory
A'
of
A
such that
that is a set into the category of abelian groups Cn,F Cn ,
sible part of gers
p,q,n.
p
(t-divisble part of
°V)p,q Identify
V)p,q
are all objects in
A'
A',
and
(Ot-divi-
for all inte-
with its image under the imbedding.
Then if (16)
xE [(Ker t)
n
(t-divisible part of
then by equation (15) we have Then by equation (16)
V)]P+l,q,
x = 9 (y), for some
g (y) = x E Ker t,
so that
By equation (14) of the Lemma, we therefore have
y E °vp,q. YE 9
-1
(Ker t).
y=z+w,
Filtered Cochain Complex where
(Ot) (z) = 0
and
g (w) = O.
361
Therefore
x=g(y) =g(z+w) =g(z) +g(w) =g(z),
g(z) =x.
By equation (16), we have that z E [g-l (t-divisible part of
V) ]p,q.
But then by equation (9) of the Lemma, of °V) •
Since also
z E [(Ker °t) Since
g (z) =x,
n
(Ot) (z) = 0,
we have that,
(Ot-divisible part of °V) ]p,q.
and
x E [(Ker t) n (t-divisible part of
is arbitrary, it follows that [(Ker °t)
zE (Ot-divisible part
gP,q
induces an epimorphism
n (Ot-divisible part of °V) ]p,q
(t-divisible part of
V) r+l,q
onto
n
[(Ker t)
V) }p+l,q, for all integers
p,q.
Combining this last result with the isomorphism in section
7, Remark 1
following Definition 5, it follows that
g
in-
duces an epimorphism from the left defect of the exact couple (2
0
)
onto the left defect of (2). The parenthetical assertion follows by duality. Let
A
be an abelian category, and let
Q.E.D.
C*= (F C*) P pE;l
be a filtered cochain complex in the abelian category
A.
Then by-Theorem 1, we have the spectral sequence (1) of the filtered cochain complex
(FpC*)pE;l'
By Theorems 1 and 1
0
,
we
have two exact couples, the exact couple (2) of Theorem 1 and a a the exact couple (2 ) of Theorem 1 , both of which have the
~ spectral sequence (1).
By the Note to Theorem 1
a natural map of bidegree (0,0);
0
,
we have
362
Section 8
of conventional bigraded exact couples starting with the inte0
ger one.
By Theorem 1
this map
,
e
induces the identity map
on the associated spectral sequences.
However, the map
e
definitely is not in general an isomorphism of exact couples. In fact,
(2°) and (2) in general have different direct limit
abutments, different inverse limit abutments, and induce different partitions of (E~"q) (p,q)E 7 X7 of the spectral sequence. However, by Theorem 2, if the abelian category
A
is closed
under denumerable direct products and denumerable direct sums, and if the functors "denumerable direct product " and "den um-
e
erable direct sum" are exact, then the mapping
of exact
couples induces an isomorphism on the left defects and on the right defects of the exact couples (2
0
)
and (2).
We will call the exact couples (2) and (2 0 C* ,
tered cochain complex
)
of the fil-
the exact couple, respectively:
the dual exact couple, of the filtered cochain complex When the partial abutments of (2), respectively of (2 0
C*. ),
exist, we shall call these the partial abutments, respectively: the dual partial. abutments, of the filtered cochain complex (F C*)pE7. p
When they exist, we will refer to the partition,
respectively: Remark 1.
the dual partition, of
(E~,q) (p,q)E7 x, .
Under the hypotheses of Theorem I, suppose that the
co-completion, co-comp(C*), of the filtered cochain complex C* = (F C*) p pE;r
exists.
Then, as in the sequence of Remarks,
Remark 1 preceding Theorem 1 co-comp (C*)
-+-
C*
0
,
we have the natural map:
Filtered Cochain Complex
363
of filtered cochain complexes, which induces a mapping:
on the associated dual exact couples.
Here, co-comp(20) de-
notes the dual exact couple of the filtered cochain complex co-comp(C*),
i.e., the exact couple obtained by the construc-
tion of Theorem 1° applied to co-comp (C*).
By the dual of
Remark 1 preceding Theorem 1°, we have that the map
SO
in-
duces an isomorphism on the spectral sequences, but in general does not induce an isomorphism on the partial abutments, if they exist; and in fact different partitions of
(2°) and co-comp(20) in general induce (EP,q)
(p,q) EIUl' •
00
We will call the
exact couple co-comp(20), the dual ~ couple of the co-completion of the filtered cochain complex Remark 2.
If
C*A
C*.
exists, then by the dual of Remark 2 pre-
ceding Theorem 1°, we have that
C*A
and
C*
have canonically
isomorphic dual exact couples. Remark 3.
If
C*A,
1\
co-comp (C*) and co-comp(C* )
all exist,
then they all have dual exact couples by Theorem 1°. by the dual of Remark 3 preceding Theorem C*
1°,
in fact
However, C*A
and
have canonically isomorphic dual exact couples, both iso-
morphic to (2°); and similarly co-comp(C*) and co-comp(C*/\) have canonically isomorphic exact couples, both isomorphic to co-comp (2°). Remark 4.
Therefore, if
such that
C*A
C*
is a filtered cochain complex
and co-comp (C*) both exist (condition auto-
matic if the abelian category
A has denumerable direct prod-
ucts and denumerable direct sums), then we have the four, in
364
Section 8
general different, exact couples, in the following diagram: (16)
S° ° )->(2)->(2 e 13 A ). co-comp(2 ° )-->(2
These exact couples are, from left to right: the dual exact couple of the co-completion of C*; the exact couple of pletion of
C*.
C*;
the dual exact couple of
C*; and the exact couple of the com-
(The mappings
13
S°
and
of exa~t couples
are given by Remark 1 preceding Theorem 1°, and by Remark 1 above, respectively. Theorem 1°).
The mapping
Notice also,
e
is given by the Note to
(by Remark 3 preceding Theorem 1°,
and Remark 3 above), that the outermost exact couples,
A
(2 )
and co-comp(20), in the diagram (16), can be interpreted alternatively as being, respectively, the exact couple and the dual exact couple of the filtered cochain complex, the co-completion of the completion of (17)
C*:
(2A) "" exact couple of co-comp (C*A), co-comp(20) "" dual exact couple of co-comp (C*A).
We have seen (by Theorem 1°; by Remark 1 preceding Theorem 1°; and by Remark 1 above), that these four exact couples, in the diagram (16), all have canonically isomorphic spectral sequences (the isomorphisms being induced by
sO,e,
and
13).
The spec-
tral sequence that these four exact couples have in common is the spectral sequence of the filtered cochain complex
C*.
However, as we have already noted, these four exact couples are all, in general, no two isomorphic; and in general have, each pair, different partial abutments, and induce in general four different partitions of
(E~,q) (p,q)E~x~.
However, the next
Filtered Cochain Complex
365
corollary shows that, under very mild conditions on the abelian category
A, they all have canonically isomorphic
left and right defects. Corollary 2.1.
Let
A
be an abelian category, such that de-
numerable direct products (respectively:
denumerable direct
sums) exist, and such that the functor "denumerable direct product"
(respectively:
"denumerable direct sum") is exact.
Suppose that co-comp(C*) exists (resp.:
that
C*A
exists).
Then each of the three maps of exact couples:
induce isomorphisms on the left (respectively: ~:
The proof shows a little bit more.
the hypothesis that "co-comp (C*) the maps
8
and
S
(resp.:
(resp. : so
phisms on the left (respectively: Proof:
and
8)
right)
right) defects.
Namely, if we delete C*A)
exists", then
still induce isomordefects.
We prove the non-parenthetical part of the Corollary.
The parenthetical part then follows by duality. That
e
induces an isomorphism on left defects follows
from Theorem 2.
co-comp(C*)
and
C*
have the same exact
couple (see Remark 2 preceding Theorem 1). (exact couple of co-comp(C*»
Therefore
and (exact couple of
C*)
have the same left defect. But, by Theorem 2 applied to co-comp(C*), (exact couple of co-comp (C*» co-comp1C*»
and (dual exact couple of
have the same left defect.
Section 8
366
Also by Theorem 2, (exact couple of
C*)
and (dual exact couple of
C*)
have the same left defect. Combining these three results, it follows that (dual exact couple of co-comp (C*» of
C*)
and (dual exact couple
have the same left defect.
SO
Otherwise stated,
induces an isomorphism on left defects.
Similarly, since
C*
and
C*A
have the same dual exact
couple (by Remark 1 above); and since by Theorem 2 applied to C*A,
the (dual exact couple of
C*A) and the (exact couple of
C*A) have the same left defect; and since likewise by Theorem 2 applied to
C*,
(exact couple of
the (dual exact couple of C*)
and the
have the same left defect; it follows
likewise that (exact couple of C*A)
C*)
C*)
have the same left defect.
and the (exact couple of
S induces an iso-
That is,
morphism on left defects.
Q.E.D.
Corollary 1.2, respectively Corollary 1.2 Corollary 1.5.
A
Let
0
imply
be an abelian category such that de-
numerable direct products of objects exist and denumerable direct sums of objects exist.
Suppose also that the functor,
"denumerable direct product" (respectively: direct sum"):
A.
complex in
AW'VV>
A
is exact.
Let
C*
"denUIl'arable
be a filtered cochain
Then the inverse limit abutments (respectively:
the direct limit abutments) of the exact couple (2'\) of the completion of co-comp(2
0
)
C*
(respectively:
of the co-completion of
of the dual exact couple C*) are all zero.
Filtered Cochain Complex Proof:
367
Follows immediately from Corollary 1.2 (respectively:
Corollary 1.2°) (respectively:
applied to the filtered cochain complex to the filtered cochain complex
Thus, under the
C*A
co-comp(C*».
(extremely mild) hypotheses of Corollary
°
1.5, the exact couples co-comp (2 ) and (2 A ) on the extremes of the diagram (16) have the property that, "all the information is contained in the inverse limit abutment, resp.:
the direct
limit abutment"- in the precise sense that the direct limit abutment, resp.:
the inverse limit
abutmen~
of the exact
A couple co-comp(20), resp.: of the exact couple (2 ), is zero. Since, by Corollary 2.1, we know that all of the exact couples in the diagram (16) have the same left and right defects, it follows that the associated gradeds of the inverse limit abutment of
co-comp(20) and of the direct limit abutment of (2A)
are isomorphic.
(Both are isomorphic to
defect)P,q»)/(right defect)P,q).
[Ker (EP,q ... (left 00
This suggests attempting to
find a natural mapping between these filtered objects that induces an isomorphism on the associated gradeds. mapping of exact couples
8
0
8
0
8°:
8
0
co-comp(20) ... (2 A ),
8
0
8°
The natural
in the diagram (16),
simply induces the zero map on
both the direct limit and the inverse limit abutments
(since
the direct limit abutmentsof co-comp(20) and the inverse limit abutments of (2A) are both zero), so this mapping cannot accomplish that end.
However, as the next proposition and
corollaries (especially Corollary 3.2.1) below show, there is a natural map of filtered objects in the opposite direction that induces an isomorphism on the associated gradeds. Proposition 3.
Let
C*
be a filtered cochain complex in an
Section 8
368
abelian category
A.
Then, for every integer
Hn(C*)
(see section 6, the Remark following Definition 3).
equivalent description of this filtration on
for all integers (1)
If
n
is
and therefore inherits a filtration from
a subquotient of en
n,
p,n.
Hn(C*)
An
is,
Then
is an integer such that the n'th direct limit
partial abutment of the exact couple (2)
exists (condition automatically satisfied if the abelian category
A is closed under denumerable direct sums), then the
natural map
is a map of filtered objects for the integer
~(Fp('Hn»
=FpHn(C*),
for all integers
n.
In fact, then
p,
and the induced mappings
are epimorphisms, for all integers (2)
Similarly, if
n
dual inverse limit abutment
p.
is an integer such that the n'th
lI~n
(that is, the n'th inverse
limit abutment of the exact couple (2°) of Theorem 1
0
)
Filtered Cochain Complex
369
exists (condition automatically satisfied if the abelian category
A
is closed under denumerable direct products), then
the natural map
is a map of filtered objects for the integer
n.
In fact, then
and the induced mappings
are monomorphisms for all integers (3)
p.
If the hypotheses of (1) and (2) above both hold for
the fixed integer
n,
then we have the diagram
of filtered objects and maps of filtered objects. each integer
p,
Then for
the induced diagram
is the canonical factorization of the mapping G (11 0
p
0
graded
11):
G (' Hn) ->- G p p
G*(Hn(C*))
of
(,,~n). Hn(C*)
Otherwise stated, the associated is canonically isomorphic to
the image of the composite mapping
Section 8
370
Proof.
First, that the filtration on
garding
Hn(C*)
F (Hn(C*» p
as a subquotient of
=Im(Hn(F C*)~ Hn(C*»
Hn(C*) Cn
induced by re-
is such that
follows easily from an appli-
p
cation of the Exact Imbedding Theorem ([I.A.C.]).
(In fact,
by the Exact Imbedding Theorem, it suffices to prove that assertion in the case in which
A is the category of abelian
groups.
~
But then (see section
tion 3) an element of sen ted by a cocycle
Hn(C*) n u EC
the Remark following Defini-
is in
iff it is repre-
such that
this is so iff the element of
Hn(C*)
But clearly
is in the image of the
Hn (F C*) ~ Hn (C*) ) •
map:
p
Next, let us prove the assertions (2) of the Proposition. That is, suppose that
n
is an integer such that
"~n
exists.
Then, the definition of the filtration on
is (17)
(see section 7, Note 2 to Theorem 2, equation (8.1); and Theorem 1
0
of this section).
A portion of the long exact sequence
of cohomology of the short exact sequence of cochain complexes
o ~ Fp C* ~ C* ~
(C* /F C*) p
~
0
is the sequence n-l
(18)
n
d ... d _ H n ( F C*) + Hn (C*) + Hn (C*/F C*)--...y p
p
Filtered Cochain Complex
371
It follows from equation (17) and this last exact sequence that (In fact, fix an exact imbedding from an exact full subcategory
°f
the category
A'
of
A
abelian groups, such that
that is a set into "on , F p ( "Hon) , H
Hn(C*/F C*) are objects in A'. Then P n by equation (17), an element x E ,,~n is in F ("H ) iff the Hn(F p C*) , Hn(C*)
and
°
p
image of y EH y
n
x
(C*)
in
y EF
p
will map under
Hn(C*/F C*) p
happen iff (H
n
y
(C*) ) •
asserted) •
Therefore an element
is zero. lJ
°
is zero.
into
F
p
(,,6°)
iff the image of
--
By exactness of
(18~
Im[Hn(F C*)~ Hn(C*)], i.e., iff p -Therefore {"o)-l(F ("Jrn»=F (Hn(C*» ~ p p ,
is in
It follows in particular that
IJ
°
~ Gp (lI~n)
as
is a mapping of
filtered objects, and that the induced mappings G (H n (C*» p
this will
G (1J0): p
are monomorphisms for all integers
This proves the assertions in (2) of the Proposition.
p. The
assertions in (I) of the Proposition follow from those in (2) by applying part (2) to the dual filtered cochain complex in the dual category
O
A
•
And the assertions
(3) follow
Q.E.D.
immediately from (1) and (2). Corollary 3.1.
8*
Suppose that the abelian category
A
is such
that denumerable direct products exist, and such that the functor "denumerable direct product": AW'VV>A
is exact.
be a filtered cochain complex in the abelian category that the filtered object
C
n
Let (0 )
on n "H = lim H (C* IF C*) p"" ~oo p
Let A
C* such
is complete, for all integers
n.
372
Section 8
be the n'th object of the inverse limit abutment of the dual exact couple of
C*,
for all integers
n.
Then the natural
mapping of filtered objects:
is an epimorphism, and induces an isomorphism on the associated gradeds. of
In fact, as filtered objects,
Hn(C*).
"~n
It follows that
"~n
is the completion
is complete, and that
is "complete but not Hausdorff", as filtered objects. kernel of the natural mapping (2)
11
o
Hn(C*)
The
is
Ker(l1o) =G+oo(Hn(C*));>:lj,m l Hn-l(C*/FpC*), p++oo
for all integers Proof:
n.
By Chapter 3 of the main text below, Corollary 1.1 and
the Note to Corollary 1.1, we have the short exact sequence (3)
(Namely, take
C~
~
= C*/F C*
tion (0) above).
i
for all integers
It follows that the mapping
phism, as asserted.
i, 11
and use equa0
is an epimor-
By Proposition 3, part (2), we know that
(4)
for all integers
p.
From equation (4), and the fact that
11
o
is an epimorphism, it follows from the Third Isomorphism Theoo 0 n rem that Gp (11 ): Gp ("H n ) + Gp (H (C*)) is an isomorphism, for all integers
n,p.
In general, for any filtered object
H,
have by definition (see section 6, Remark 1 following Corol1ary 4.1) that
G+ H = 00
n F H. Therefore by equation (4) and pEi?' P
we
Filtered Cochain Complex
373
section 2, the Lemma following Definition 5, part (1), it follows that
Since
,,§n
is an inverse limit abutment associated to an exact
couple (namely, to the dual exact couple (2 the filtered cochain complex have that
,,~n
is complete.
and therefore Ker(~
o
G+00
(,,~n) = 0 •
n
) =G+oo(H (C*».
0
)
of Theorem 1
0
of
C*), by section 7, Theorem 2, we In particular,
,,§n
is Hausdorff,
Therefore equation (5) implies that
This observation and equation (3) imply
conclusion (2) of the Corollary. Since of
~o
Hn(C*).
quotient-object Hn(C*).
is a quotient-object
Equation (4) and the fact that
phism implies that
from
,,~n
is an epimorphism,
Fp
,,~n
(,,~n) = ~o (F p of
n H (C*)
n (H (C*») •
~o
is an epimor-
Therefore, the
has the:til tration induced
That is,
(6) as filtered objects. (7)
Since
,,§n
is complete, it follows that
is complete.
Therefore, by definition (see section 7, the Remark following Corollary 7.1), we have that Hausdorff".
Hn(C*)
Also, it follows readily from equation (7)
using section 7, Proposition 4) that completion of
is "complete but not
Hn(C*)
Hn(C*)/G+oo(Hn(C*»
as filtered object.
(e.g., is the
This observation
and the isomorphism (6) of filtered objects implies that
,,~n
is the completion of
Q.E.D.
Hn(C*)
as filtered object.
Section 8
374
Corollary 3.1
0
Suppose that the abelian category
•
A
is such
that denumerable direct sums exist, and such that the functor "denumerable direct sum":
AW'V'u> A
is exact.
Let
filtered cochain complex in the abelian category the filtered object
n C
C*
A,
be a such that
is co-complete, for all integers
n.
Let (0)
be the n'th object of the direct limit abutment of the exact couple of
C*,
for all integers
n.
Then the natural mapping
of filtered objects: jJ: 'Hn+Hn(C*)
(1)
is a monomorphism, and induces an isomorphism on the associated gradeds. tion of that
In fact, as filtered objects, Hn(C*).
Hn(C*)
The
is the co-comple-
is co-complete, and
cokernel of the natural mapping
jJ
is:
Cok(jJ) =G_oo(Hn(C*)) '''d!ml Hn+l(FpC*), p++oo
for all integers Proof:
n.
Follows by applying Corollary 3.1 to the dual filtered
cochain complex
8*
o Corollary 3.1 .1. lary 3.1°. in
'H
n
is "co-complete but not co-Hausdorff", as fil-
tered objects. (2)
It follows that
n
'H
A.
Let
in the dual category Let
C*
A
O
A
Q.E.D.
•
be an abelian category as in Corol-
be an arbitrary filtered cochain complex
Then for each integer
n, Hn(co-completion
C*)
is "co-
complete but not co-Hausdorff" as filtered object; and we have
Filtered Cochain Complex
375
a canonical isomorphism of filtered objects,
where
'H
n
is the n'th direct limit abutment of the spectral
sequence of the filtered cochain complex Corollary 1.1.
C*
as defined in
Also,
n n G-00 (H (co-comp C*)) ~ liml H (F _C*) -+ p' p-++oo for all integers Proof:
n.
As noted in Remark 2 preceding Theorem 1°, the natural
map of filtered cochain complexes co-comp (C*) -+ C* induces an isomorphism on the exact couples as defined in Theorem 1.
Therefore, replacing
C*
by co-comp(C*) if necessary,
the Corollary reduces to the caSE in which
C*
is co-complete.
Then the conclusions follow from Corollary 3.1°. Remark:
Under the hypotheses of Corollary 3.1°, suppose in
addition that the abelian category
A is such that the func-
tor "denumerable direct limit" is exact.
Then of course every
A is "co-comp. but not co-Hausd." Also,
filtered object in
in this case, obviously
l~ml:: O.
Therefore, in this case,
p++ro
co-comp C* =F_roC*, and the conclusions of Corollary 3.1 °.1 can then be written:
for all integers 1.3.
n.
This gives another proof of Corollary
Thus, in the special case that the abelian category
A
Section 8
376
is such that the functor "denumerable direct limit" is exact, 0
Corollary 3.1 .1 reduces to Corollary 1.3. Corollary 3.1.1. lary 3.1. in
A.
Let
Then
Let C*
A be an abelian category as in Corol-
be an arbitrary filtered cochain complex
Hn(C*A,
is "complete but not Hausdorff" as fil-
tered object, and we have a canonical isomorphism of filtered objects
,,~n
where
is the n'th dual inverse limit abutment as defined
in Corollary 1.10 chain complex
,
C*.
of the spectral sequence of the filtered coAlso,
canonically, for all integers Proof:
n.
Follows by applying Corollary 3.1 0 .1 to the dual fil-
tered cochain complex Corollary 3.2.
8*
AO •
in the dual category
Suppose that the abelian category
A is such
that denumerable direct sums and denumerable direct products of objects exist, and is such that the functors "denumerable direct sum" and "denumerable direct product", exact. category
Let
A
C*
are
be a filtered cochain complex in the abelian
such that
for all integers
Aw'VV> A,
n.
n C
is both complete and co-complete
Then for every integer
n,
Hn(C*),
as
filtered object, is both "complete but not Hausdorff" and "cocomplete but not co-Hausdorff". (1)
We have the natural mappings
377
Filtered Cochain Complex
which are mappings of filtered objects that induce isomorphisms on the completions of the co-completions.
o n Hn (C* YG +00 (H (C*) ) R> "Hn
(2)
Also Hn (C*)
is the completion of
as filtered object, and (2°)
F_ooHn(C*) ~ 'H n
is the co-completion of
filtered object, for all integers (3)
and
n.
Follows immediately from Corollary 3.1 and 3.1
Corollary 3.2.1.
as
In addition,
G+ooHn(C*)R> liml Hn-l(C*/F C*), p++oo p
for all integers Proof:
n.
Hn(C*)
Let
0
•
A be an abelian category obeying the
hypotheses of Corollary 3.2.
Let
C*
be an arbitrary filtered
cochain complex in the abelian category
A.
Then consider the
sequence (16)
o ",0 0 e S 1\ co-comp ( 2 ) ~> (2 ) + (2) + (2 )
of exact couples described in Remark 4 following Theorem 2 above. Then for all integers
n
there is induced a natural map of
filtered objects: (17)
(n'th direct limit abutment of
(21\»
+
(n'th inverse limit abutment of co-comp (2 in the opposite direction to the composite map exact couples in the sequence (16).
0
S
», 0
e
0
SO
of
The map of filtered objects
(17) induces an isomorphism of filtered objects on passing to the completion of the co-completion.
378
Section 8
Notes:
The proof shows that the map (17) naturally factors,
1.
as map of filtered objects, through
Hn(co-comp(c*A)); that this
latter filtered object is both "co-complete but not co-Hausdorff" and "complete but not Hausdorff"; and that the completion of
n A H (co-comp(C* )) is the right side of equation (17), while the co-completion of
n A H (co-comp (C* ))
is the left side of equa-
tion (17). 2.
The kernel of the map (17) is
A limit abutment of (2 )), morphic to is
and is also
liml Hn-l(C*/F C*). p-++oo p
G+ oo (n'th direct
G+ro(Hn(C*)),
The cokernel of the map (17) 1\
G_oo(n'th inverse limit abutment of co-comp(2 )), G_oo(Hn(C*)),
also Proof:
and is isomorphic to
As noted in Remark 4
and is iso-
and is
liml Hn+l(F C*). p-++oo p
following Theorem 2, the exact
o
couples (21\) and co-comp(2 ) are canonically isomorphic to the exact couple and, respectively, the dual exact couple, of the 1\
filtered cochain complex co-comp(C*). then follow from Corollary Remarks 1.
,,~n teger
3.:~.
Q.E.D.
Under the hypotheses of Proposition 3, if
both exist for a given integer n,
The Corollary and Notes
and for all integers G
p
EP,n-p 00
(lJ
o 0
p,
n,
n
and
then for the fixed in-
we have a diagram:
lJ)
«map induced bye) (identity map)
'H
EP,n-p 00
Filtered Cochain Complex
EP,n-p.
a subquotient of
00
R,
'
resp. :
379
S, denotes the thereby
induced relation (not in general a mapping) from subquotient Gp (,,~n) ,
,
map induced by identity map.
into
00
It is not difficult to see that this diagram of A
~
c*)/(infini~e) p t-tors~on
~
t oHn(F f*) / (infini ~e ) p+ t-tors~on
is commutative.
But since
= Hn (natural
A,
map induced by
Hn(F C* nat.> C*/F C*) ~~e7 t)n(ig] p map p+l >f~n~tely t di visible part of Hn(C*/Fp+lC*»
relation induced by hP,n-p
hP,n-p
is commutative.
It is equivalent to prove that the diagram of objects
and relations in the abelian category
Hn(F
The bottom map is the
whcih by the Note to Theorem 1 0 is the
G
relations in the abelian category Proof:
EP,n-p.
relation induced by ~p,n-p
~p,n-p = Hn (inclusion) and
projection), this latter follows from
commutativity of the diagram of objects and mappings in the abelian category
A,
Section 8
380
> Hn(C*/F
1 H
n
n H (G
2.
p+l
C*)
(indu,ionl
p
(C*)).
Q.E.D.
As noted in Remark 4 following Theorem 2, under the
hypotheses of Theorem 1, we have that the composite
S c80 SO
of the sequence of maps of exact couples (16) induces an isomorphism of the associated spectral sequences, and therefore also of the corresponding
E co -terms.
tion 3, this isomorphism of
As noted just prior to Propos i-
Eoo-terms induces, by passing to the
subquotients, an isomorphism from the associated graded of the inverse limit abutment of co-comp(2 0 of the direct limit abutment of
)
A (2 ).
onto the associated graded By commutativity of the
diagram in Remark 1 above, it follows that this just described isomorphism of associated gradeds is the inverse of the isomorphism of associated gradeds induced by the map of filtered objects (17) of Corollary 3.2.1.
A be an abelian category obeying the hypotheses of
Let
Corollary 3.2.1, and let complex in
A.
C*
be an arbitrary filtered cochain
Then, by Corollary 3.2.1, we have that (the A
direct limit abutments of the exact couple (2 ) of the completion of
C*)
and (the inverse limit abutments of the dual exact
o couple co-comp(2 ) of the co-completion of by very much.
C*)
do not differ
In fact, by Corollary 3.2.1, Note 1, these both
do not differ very much from the sequence of filtered objects
Filtered Cochain Complex (H n (co-comp(C* "
»)n~.
381
We call these latter filtered objects
the integrated partial abutments of the filtered cochain complex
C*,
and occasionally will denote them
Then, by Corollary 3.2.1, the completion (respectively: co-completion) of the n'th integrated partial abutment C*
Hn
of
is canonically isomorphic to the n'th direct (respectively:
inverse) limit abutment of (2")
(respectively: of co-comp(2 o ».
A portion of Corollary 3.2.1 can be summarized as Corollary 3.2.1.1. A
(The integrated partial abutments).
Let
be an abelian category such that denumerable direct products
and denumerable direct sums of objects exist, and such that the functors, "denumerable direct sum" and "denumerable direct product", AW'VV>A chain complex
G)
are exact.
C*
in
A,
Then, for every filtered co-
we have
A conventional bigraded spectral
sequence starting
with the integer one, the spectral sequence (1) of the filtered cochain complex
C*.
~ A subobject
(right defect), and a quotient object (left
defect), of the bigraded obJ'ect
(EP,q) 00
(right defect)
®
C
(p,q)E'!'x'!"
such that
Ker ((E~,q) (p,q) Ez x71 ... (left defect»;
A sequence
Hn,
nE7l,
of filtered objects, called
the integrated partial abutments, each of which is "complete but not Hausdorff" and "co-complete but not co-Hausdorff"; and ~ An isomorphism of bigraded objects from
onto the sub-quotient of
[Ker( (E~,q) (p,q)E'!'X7l "'(left defect»
(EP,q) 00
(p,q)E'!'x'!'.'
]/(right defect).
Given a perfectly general filtered cochain complex
C*
in
Section 8
382
A as in Corollary 3.2.1.1, the data, ~
an abelian category
Q),
and
GD
of Corollary 3.2.1.1 can be thought of as being
"the closest thing to an honest abutment that the spectral sequence of the filtered cochain complex thing, these data are clearly self-dual.
C*
has".
For one
(The partial
abutments of each of the exact couples co-comp(20),
(2°),
(2),
1\
(2 ) are not self-dual, but switch between themselves under duality).
Also, all of the data of the partial abutments of co-
comp(20) and (2") are contained in the integrated partial abutments, i.e., in the data
0, G), ®
(by the observation
immediately preceding Corollary 3.2.1.1 and by Corollaries 1.2 and 1.2°). co-comp(20),
The fact then, Corollary 2.1, that the exact couples: (2°),
(2) and
(21\)
all have the same left and right
defects can then be written equivalently as Corollary 3.2.1.2.
Under the hypotheses of Corollary 3.2.1.1,
let
respectively:
(IHn,"Hn)nEi.:'
(,§n,,,§n)nEi.:'
abutments of the exact couple (2), respectively: exact couple (2°), of the filtered cochain complex for all integers
n,p
be the partial of the dual C*.
Then
we have the short exact sequences:
(18)
The mapping
8:
(2°) ~ (2) of exact couples (of the Note to
Theorem 1°) defines, for all integers
nand
p,
a mapping of
short exact sequences from (18°) into (18), that is the identity on the middle terms. Remarks 1.
Corollary 3.2.1.2 of course explains the terminology
"integrated partial abutments" for the filtered objects
Hn,
Filtered Cochain Complex n EZ;
383
since by equation (18) they "tie together" the direct
limit and inverse limit abutments of the filtered cochain complex
C*,
while still classifying "exactly as much" of Hn
(Equation (18°) interprets
similarly viz-a-viz the direct
and inverse limit dual partial abutments). 2.
Corollary 2.1, or the equivalent formulation Corol-
lary 3.2.1.2, shows that, if a filtered cochain complex
C*
has
a non-zero left or right defect, then there is "no way" to ever
E~,q
classify this part or parts of "abutment".
by any kind of meaningful
From this point of view, the left and right defects
can be thought of as being the "cancerous part" of
EP,q 00
,
since
they can never be so classified; and on the contrary "every other part" of
is classified in the appropriate fashion
o by any of the four sets of partial abutments (of co-comp(2 ) , A of (2°), of (2) or of (2 )),
and also by the integrated partial
abutments. 3.
exact couple (2), resp.: (18), resp.:
(E~,q) (p,q)E~x~
The partition of
(18°),
(2°),
induced by the
can be described from equation
of Corollary 3.2.1.2 as follows.
First,
take the image of the composite of the monomorphisms: G (' HP +q ) .... G (H P +q ) .... EP,ql (right defect) p,q p p 00 ,
pre-image of this subgroup of to obtain
'E~/q.
E~,q/(right defect)P,q
Then of course,
°
a P , q "EP,q) The dual partition ('E 00
'
00
and then take the
(p,q)~~
in
"E P , q = EP ,q I' EP,q. 00
of
00
( EP,q)
00
(p,q)~~
can be determined similarly from (18°). 4.
From Corollary 3.2.1.1, it follows that necessary
and sufficient conditions for the integrated partial abutments of the filtered cochain complex
C*
to be an honest abutment
384
Section 8
(in the sense of section 7, Definition 1) is that the left defect and right defect both be zero. 5.
By definition of the integrated partial abutments,
and by Corollary 2.1, we have that, under the hypotheses of Corollary 3.2.1.1, that the ~
("abutment-like") data,
of Corollary 3.2.1.1 is invariant under replacing the fil-
tered cochain complex 1\
C*
co-comp(C* ).
pletion,
with the completion of its co-com(This is, of course, also true for
o the partial abutments of co-comp(2 ) and of
(21\)--which sets of
partial abutments are, in fact, completely determined by the integrated partial abutments, i.e., data
(]),
CD, 0,
as we
have already seen--but is, of course, not true in general for the partial abutments of (2) or of 6. and
0
o (2 )).
0,
Thus, again, to summarize, the data
(1),
is "the closest thing to an honest abutment" that
the spectral sequence
(1) of the filtered cochain complex
C*
has; and this data actually is an honest abutment iff both the left defect and the right defect are zero. Because of the special importance of the category of abelian groups, it is worthwhile noting that simplifications occur in Corollary 3.2.1, etc., in that case.
The notable simplifica-
tions all arise from the fact that the functor, "denumerable direct limit", is then exact. Corollary 3.2.1.3.
Let the hypotheses be as in Corollary 3.2.1.1,
and suppose in addition that the abelian category that the functor, (1)
A
is such
"denumerable direct limit", is exact.
The integrated partial abutments
Hn,
n E~ ,
Then are
co-complete, and "complete but not Hausdorff".
Filtered Cochain Complex (2)
The right defect vanishes.
(3)
For all integers
p,q,
385
we have the short exact
sequence 0-+ G HP +q -+ EP,q -+ (left defect)P,q
->-
O.
P
Note:
In this case, we have that the n'th integrated partial
abutment
n H
=
n H (co-comp (C*A»
is canonically isomorphic as
filtered object to the (n'th direct limit abutment of the exact couple (2A) of the completion of
C*),
for all integers
n.
On the other hand, the (n'th inverse limit abutment of the dual o exact couple co-comp(2 ) of the co-completion of
C*)
in this
case is both complete and co-complete, and is canonically isomorphic as filtered object to Proof: G
By Corollary 3.2.1, Note 2, we have that
(Hn(C*»
""liml Hn+l(F C*). Since "denumerable direct limit" p-++oo p n is by hypothesis exact, this latter is zero. Therefore H is _00
co-Hausdorff.
This and
(t)
of Corollary 3.2.1.1 implies con-
clusion (1). Next, by Corollary 1.3, we have that the direct limit abutment of the spectral sequence of the filtered cochain complex C*
is perfect.
Conclusion sion
(3)
Otherwise stated, the right defect is zero. of Corollary 3.2.1.1 then simplifies to conclu-
of this Corollary.
for all integers
n,
The fact that
n H
is co-complete,
and Note 1 to Corollary 3.2.1 then imply
the Note to this Corollary.
Q.E.D.
We conclude the theorems of this section with a proposition about induced mappings of filtered cochain complexes. Proposition 4.
Let
A
be an abelian category obeying the
Section 8
386
(very mild) hypotheses of Corollary 3.2.1.1. be filtered cochain complexes in
A,
and let
a map of filtered cochain complexes(*). integers
n,p,
Let
C*
and
f*:C*+ 0*
0* be
Suppose that, for all
we have that
(0)
A.
is an isomorphism in the category "suppose that
f*
(It is equivalent to say, of the
induces an isomorphism along
spectral sequences of the filtered cochain complexes 0*"). (1)
C*
and
Then The map:
(EP,q(f*» r p,q,rE'l' r> 1
induced by
f*
is an
isomorphism of spectral sequences, from the spectral sequence of (2)
C* f*
onto the spectral sequence of
0*.
induces an isomorphism on the left defects, and an iso-
morphism on the right defects. (3)
The mappings induced by
f*
on the integrated partial
abutments are isomorphisms of filtered objects, Hn (co-comp (f J\ »: Hn (co-camp (C 'Ii' » ~ + Hn (co-comp (0* A». Note 1.
In addition,
f*
couple of the completion of completion of
0*;
induces isomorphisms form the exact C*
onto the exact couple of the
and also isomorphisms from the dual exact
couple of the co-completion of
C*
onto the dual exact couple
t*J That is, a map in nthe category of filtered objects in Co(A). That is, fn:Cn+O is a map in A, for all integers n, such that fn(FpC n ) C FpOn, for all integers n,p, and n n n+l n . such that d o * 0 f = f 0 d for all 1ntegers n. C*'
Filtered Cochain Complex of the co-completion of 2.
387
0*.
If, in the hypotheses on the abelian category
A
in
the Proposition, we replace the hypothesis on the abelian cate-
A,
gory
that
"A
obeys the hypotheses of Corollary 3.2.1.1"
by the weaker hypotheses, that "the abelian category closed under denumerable direct sums (respectively:
A is products)
of objects and the functor "denumerable direct sum (respectively: product) is exact", then the proof of the Proposition shows that conclusion (1); sion i2);
the second (respectively: first) part of conclu-
and the second (respectively:
first) part of Note 1,
remain valid. Remark:
A theorem in [E.M.l is equivalent to the assertion that,
if we havt all of the hypotheses of the Proposition except perhaps hypothesis (0), then conclusion (3) of Proposition 4 holds if there exists a positive integer isomorphism, for all integers Proof:
r
is an
l p,q.
The spectral sequence; the left and right defects (by
Corollary 2.1); the integrated partial abutments (by definition); 0
and the exact couples (l') and co-comp (2
)
(by equations (17) of Re-
mark 4 following Theorem 2); of a filtered cochain complex
C*,
all actually depend, up to canonical isomorphisms, on co-comp(c~). Therefore, replacing
C*
and
0*
by the completion of their
co-completions, it suffices to prove the Proposition in the case that
C*
and
0*
are both complete and co-complete.
But then, for every integer
i
~
0,
f*
induces a mapping
from the long exact sequence of cohomology associated to the short eyact sequence of cochain complexes,
Section 8
388
O-+G+,(C*) p 1
(4)
F (C*)
{
Fp+~+i (C*)
1
--;;.0
into the corresponding long exact cohomology sequence with replacing i,
"C*".
"0*"
Therefore by the Five Lerruna and induction on
it follows that, for every integer
i..:: 0,
the mapping
f*
A,
induces isomorphisms in the category
Hn(F (C*)/F +' (C*))~Hn(F (O*)/F +' (0*)),
(5)
P
p
for all integers n
F (C ) p
1
n,p.
P
P
1
By Lerruna 1 of section 6, we have that
is complete for all integers
Therefor~ by Chapter
n,p.
3 of the main text below, Corollary 1.1 and the Note to Corollary 1.1, we have the short exact sequences
for all integers
n,p.
The map
f*
induces a mapping of these
short exact sequences into the analogous short exact sequences for
0*.
Therefore, by the isomorphisms (5) and the Five Lerruna,
it follows that the maps in the category
A induced by
f*
are
isomorphisms (6)
for all integers
~*: 8* -+ 8* category
n,p.
Applying equation (6) to the map
of the dual filtered objects in the dual abelian
AO,
we have likewise that, the maps induced by
are isomorphisms in the category
A,
f*
Filtered Cochain Complex for all integers Po = 0,
f*
n,p.
389
But, for any fixed integer
Po'
say
induces a map from the long exact sequence of coho-
mology of the short exact sequence of cochain complexes,
o -T F
C*
-T
C*+C*/F
Po
C* + 0, Po
into the corresponding long exact sequence with "C*".
Therefore, equations
fixed integer
Po'
the fixed integer induced by
f*
(6)
for all integers
and equations (6 -Po'
0
)
"0*" n
replacing and the
for all integers
nand
and the Five Lemma, imply that the maps
are isomorphisms in the category
A,
(7)
for all integers abutments", since tegers
n,
n. C
By definition of the "integrated partial n
is complete and co-complete for all in-
we have that (n'th integrated partial abutment of
the filtered cochain complex
nAn C*) (=H (co-comp(C*) )) = H (C*),
and (p'th filtered piece of the n'th integrated partial abutmentoT the filtered cochain complex for all integers "C*".
n,p; and similarly with
Therefore, equations
"0*"
replacing
(6) and (7) above imply conclusion
(3) of the Proposition. Next, notice that C*
and
vp,q
and
EP,q
in the exact couple of
are
EP,q:HP+q(G C*), P
for all integers
p,q;
and similarly with
0*
replacing
C*.
390
Section 8
Therefore, from the equations
for
C*
and
D*,
we have
and by the hypo-
induces an isomorphism along
f*
that
(6)
theses of the Proposition, f*
induces an isomorphism along
EP,q,
Therefore
for all integers
p,q.
f*
induces an isomor-
phism from the exact couple of the filtered cochain complex onto the exact couple of the filtered cochain complex implies conclusions
(1)
C*
D*.
This
and (2) of the Proposition, and also the
first partof Note 1 to the Proposition.
The second part of
Note 1 to the Proposition follows from the first part of that 000
Note applied to the induced mapping
f*: D*
tered objects in the dual abelian category Remark:
-+
C*
of the dual fi 1-
O
A
Q.E.D.
In the next section, we will show that, under the
hypotheses of Corollary 3.2.1.1, if the spectral sequence is such that the cycles stabilize (see section 9, Definition 1), then the left defect is zero.
(See section 9, Corollary 4.1).
(If the cycles stabilize "in a certain uniform manner", then the integrated partial abutments are also complete, see section 9, Proposition 5 and Proposition 5.1). Finally, we conclude this section with a few examples. Example 1.
Let
A
be a ring such that we have an element
in the center of the ring and is not a unit.
(E.g.,
A
such that
A=zr,
ule
M
is not a zero divisor
t = any non-zero integer.
A = 0, a discrete valuation ring, and meter).
t
t
Or
t =a uniformizing para-
Then it is easy to see that there exists a left A-modsuch that there exists an element
x EM
is t-divisible, but not infinitely t-divisible. such modules such that
M
tx = O.
such that
x
And in fact,
can be constructed such that the element (See Chapter 4 of the main text, below)
x
is
Filtered Cochain Complex Let
pO, pI
391
be projective left A-modules and
a homomorphism of left A-modules such that
M~Cok(dO).
denote the localization of the ring element
t,
n
and let
C = A [t
-1
1
® A
dO :pO
A
n
p ,n = 0,1.
-+
pI
Let
at the central
Then
C*
is a
cochain complex of left A-modules that is zero in dimensions ;' 0,1.
Define a filtration on
all integers
n,p.
plication by
t P"
C*
by defining
Then
C* = (F C*) is a filtered cochain p pEzr complex in the category of left A-modules. The mapping "multi-
plex
P*( =FOC*)
Cok(dO) ~M. chain complex
induces an isomorphism from the cochain comonto
FpC*.
Therefore, in the exact couple of the filtered coC*,
we have that
to multiplication by
p
-+
vp - l , 2-p
and that
corresponds
t.
But then, for all integers (left defect)P,-p~
vP ' I-p = HI (F C*) ~ M,
t P ' I-p :vP ' l-p
under these isomorphisms
y EM:ty '" 0,
I
that
By
Hl(FpC*) ~Hl(p*)
It follows that
y
p,
1l1
and such
is t-divisible
Y EM:ty = 0, and such } that y is infinitelY. t-divisible
hypothesis, the right side of this equation has the non-zero
element, the coset of all integers
x.
Therefore,
(left defect)P,-p;,0,
for
p.
Therefore, the zero'th inverse limit abutment
"HO,
and by
Corollary 2.1 also the zero'th dual inverse limit abutment of the filtered cochain complex
,,~o,
C* = (F C*)
is not perfect. pEl' By Remark 4 following Corollary 3.2.1.2, it follows also that the zero'th integrated partial abutment
p
(=HO(C*A)
in this
case) is not an honest abutment in the sense of section 7, Definition 1. Remark:
By section 7, Corollary 2.3, one cannot make a similar
Section 8
392
counterexample, about right defects and non-perfect direct limit abutments, or about non-perfect dual direct limit abutments, in any abelian category in which denumerable direct sums exist and such that the functor "denumerable direct limit" is exact. ever, in the dual of the category of left A-modules Example 1), the dual filtered cochain complex
8*
(A
as in
C*
of
How-
is
such that the zero'th right defect is non-zero, such that the zero'th direct limit abutment is not perfect, and also is such that the zero'th dual direct limit abutment is not perfect.
And
the zero'th integrated partial abutment is not an honest abutment in the sense of section 7, Definition 1. Example 2.
Let
left A-module
A,t M,
be as in Example 1.
such that
Then there exists a
M has no non-zero infinitely
t-divisible elements, such that there exists a non-zero divisible element xEM
x
E;
M,
and such that every non-zero divisible element
is not a t-torsion element
for all
i.::: 0).
left A-modules
(i.e., is such that
i
tx-j.O,
Then construct a filtered cochain complex of
C*,
concentrated in dimensions
Example 1, using this left A-module for the exact couple of
C*,
t).
Then, as in Example 1,
we have that
and that under these isomorphisms, (left multiplication by
M.
-j. 0,1, as in
tP,l-p
corresponds to
Then, in the notations of [I.L.]
(see also section 7, Remark 2 following Definition 5) we have that the deviation of the inverse system
(6 ),of sec1
tion 7, Note 2 to Theorem 2, applied to the exact couple of the filtered cochain complex
C*,
is such that
Filtered Cochain Complex
tP+2,-p-l
+1Dev( ... --------~> vP , p
I
~
tP+l,-p --------..;»
V
p -p+l
(divisible part of M) (infinitely divisible part of (divisible part of
for all integers
i.
'
393
tP,-p+l
--'---->... )
1i
M)
M) '10,
Therefore the deviation of the inverse
system (6 ) is non-zero, and also has no non-zero t-torsion. 1 By section 7, Remark 2 following Definition 5, we have (left defect) p ,- p = {x
~[Dev(61)
f+l: tx=O}
={x E(divisible part of
M): tx=O}
= 0,
for all integers
p.
Therefore in this example the (p,-p) 'th
left defect is zero for all integers
p,
so that
e.g. the
zero'th inverse limit abutment is perfect, even though the deviation of the corresponding inverse system,
(6 ) of Note 2 to 1
Theorem 2 of section 7, is non-zero. Example 3.
A,t
as in Example 1, let
P*
be a cochain complex
of t-torsion-free left A-modules such that
is not a t-divisible left A-module , and such that there exists an element tx = 0.
x
Define
in
HO(P*) that is t-divisible and such that
C* = A [t -1] ® P*,
all integers
n,p.
A
Then
C*
is a filtered cochain complex of left A-modules, and
using section 5, Theorem 4, it is easy to show that
'E~,l-P~Hl(p*)!(t-torsiOn) 'I t
{a},
Section 8
394
'" "EP,l-p ,=
1x
00
E HO (rp*) :tx =
x
°
and such that
I ;i{O}.
is t-divisible induced by
Therefore in this case the partition of the exact couple of the filtered cochain complex trivial.
C*
is non-
In this case, the first direct limit abutment is per-
feet; the first inverse limit abutment is perfect iff every element
XEHO(P*)
such that
tx =
ble, is infinitely t-divisible. cochain complexes
C*
°
and such that
x
is t-divisi-
(Examples can be given of such
that do, and that do not, obey this last
condition) . When this is so, both the first dire lim. abut. and
for all integers zero.
p;
therefore
'Hl
, l-p .,.. "E P ~ {O} 00
'E~' l-p,
the first inv. lim. abut. are perfect, and and
"Hl
,
are both non-
However, as always, the partition of
induced by the exact couple co-comp(2 A (2 ),
Theorem 2), resp.:
0
)
(of Remark 4 following
is such that the direct limit (resp.:
inverse limit) abutments are all zero, and is such that the right (resp.:
left) part of the partition of
(EP,q) 00
is zero.
Therefore, the three exact couples:
and (2A) must all induce different partitions of all integers
p,
(p,q) El'x'l'
co-comp(2 0 EP,l-p 00
(2),
) ,
'
for
and also induce different (non-isomorphic by
the natural map of exact couples) sets of partial abutments. Since the filtered cochain complex
C*
is co-complete, in this
case the exact couple (2°) is isomorphic to the exact couple co-comp(2 of
0
) ,
and these two therefore induce the same partition
(E~,q) (p,q)E'l' xl'
and have canonically isomorphic sets of
partial abutments. Remark.
Examples 1,2 and 3 above all come from Bockstein spec-
Filtered Cochain Complex
395
tral sequences--see Chapter 1 of the main text below.
All fil-
tered cochain complexes coming from Bockstein's are co-Hausdorff (and also Hausdorff). limi~
direct
Therefore, if the functor "denumerable
is exact
left A-modules,
A
(as it of course is in the category of
a ring), then all such filtered cochain
complexes are co-complete, and therefore are such that co-comp(2 and (2
0
)
are isomorphic exact couples, and therefore yield iso-
morphic sets of partial abutments, and identical partitions of (EP,q) 00
(p , q) Ei?' xJ1 •
Example 4.
Let
C*
be a cochain complex of abelian groups,
such that we have a sUb-cochain complex
E*
and an integer
n
o
such that the induced mapping: -1
n
H
0
-1
n
(C*)
-+
H
is not an epimorphism.
(C*/E*)
0
(It is very easy to construct such
examples for each integer
no'
since the functor
"nO'th coho-
mology group" of course does not preserve epimorphisms). Po
be any integer, and define
F C* == P
Then
Let
C*
couple of
0,
if
E* ,
if
p ~ PO + 1
is a filtered cochain complex, and for the dual exact C*,
we have
~p,n-p==Hn(C*/F
p+l
C*)
'
all integers
Using section 7, Theorem 2, we see that
n,p.
0
)
Section 8
396
Therefore G
(, oHnO)~~
Po
Im(HnO-l(C*/E*) -+Hno-l(C*/E*» Im(HnO- l (c*) -+ HnO- l (C*/E*» n -1 H 0 (C* /E*»
co-comp(2 co-comp(2
0
) ) ,
n -1 0
(C*)-+
{O} •
op n-p 'E 0' 0 0"1
It follows that 0
"I
= Cok (H
0
Since, for the exact couple
we always have that the direct limit abutments of are always
and the right part of
zero, it follows that, for the filtered cochain complex of abelian groups
C*
constructed in this Example, we have that
the dual exact couple co-comp(2 0 ) of the co-completion of C* and the dual exact couple (2 0
)
of
C*
must both have different
no'th direct limit abutments, and must also induce different p ,n -p partitions of E 0 0 0 00
Example 5.
Taking the direct sum of the filtered cochain com-
plex in Example 3 with the filtered cochain complex in Example 4, yields a filtered cochain complex, call it groups such that the four exact couples:
C*,
of abelian
the dual exact couple
of the co-completion; the dual exact couple; the exact couple; and the exact couple of the completion; of the filtered cochain complex
C*,
are such that they all yield four different, pair-
by-pair non-isomorphic,
sets of partial abutments; and such that
the four partitions of quence of the filtered cochain complex
of the spectral seC*
induced by these
four exact couples are all different. Example 6.
Let
0
be a discrete valuation ring containing
the ring of integers as a subring, such that there exists a rational prime
p
that is not a unit in
O.
Let
t
be a
Filtered Cochain Complex generator for the maximal ideal of 0=7
(p)
= {!!.l E (j):
p
n
O.
does not divide
0=7 p ,
Another example is
examples, one can take
nomial ring in one variable over
Let 0,
the usual derivative with respect to complex of
i C*
Hn(C*),
n},
where
~
C*
and let T.
i
and similarly with
"C*A"
tion if,e.g., i.::.O
then
~
is a cochain 0,1.
Intro-
that
-1,
replacing
"C*"
(since by defini-
Hn(c*))
Im(H n (tic*)
-+
Hn (C*)) = tiHn (C*) ,
Then it is shown, in Chapter 4, in an
Example, of the main text below, that ly complete for the t-adic topology.
Hl(C*A)
be
Then the filtration on
-+
follows that
cl
is the t-adic filtration, such
1
that the filtration on
C*
-+
n, i.
F,Hn(C*) = Im(Hn(F,C*)
n).
the poly-
dO: cO
Then
for all integers
Hn(C*A),
for all integers
In both these
by defining
-1,
1
is any prime.
= c = 0 [Tl,
cO
is a filtered cochain complex. and on
p
l
O-modules concentrated in dimensions
duce a filtration on
Then
(For example,
the p-adic integers.
= p. )
t
397
HLlc*A)
Hl(C*A)
is not t-adical-
Since we have just observed
is the t-adic filtration, it
is not complete as filtered object.
Since the filtered object
n C
is co-discrete, we have that
c
n
Section 8
398
is co-complete, for all integers
n.
Therefore co-comp(c~) =
is the n'th integrated partial abutment in the sense of Corollary 3.2.1.1 of the filtered cochain complex
C*.
Therefore we have an example of a filtered co-
chain complex of abelian groups in which the first
inte~.
part.
abutment is not complete, and therefore by Corollary 3.2.1.1,
conclusion~,
also not Hausdorff.
By Corollary 3.2.1, it
follows also that the first direct limit abutment of the exact couple (2A) of the completion of is also not Hausdorff.
C*,
is also not complete and
(In this Example, it is easy to see that
the first direct limit abutment
'Hl,
which since
complete is isomorphic by Corollary 1.3 to although not complete. n 'H "" Hn(C*),
n 1-1,
C*
is co-
Hl(C*), is Hausdorff,
The other direct limit abutments
are complete, in fact have finite filtra-
tions; in fact, are finitely generated as
O-modules.
(In fact,
~ ~, 1.) (And the inv. lim. abuts. are all zero) .)
they are: Example 7.
By Coroll'ary 3.2.1.3, itisimpossible to find a
filtered cochain complex in the category of abelian
groups
such that the integrated partial abutments are not co-complete. However, in the dual of the category of abelian groups, the dual
8*
of the filtered cochain complex of Example 6 is a
filtered cochain complex such that the (-1) 'st integrated partial abutment is not co-complete (and therefore by Corollary
Cl),
3.2.1.1, conclusion Example
8.
Let
A
is not co-Hausdorff.)
be the direct product of the category of
abelian groups and of the dual of the category of abelian groups.
Then
A is an abelian category obeying the hypotheses
of Corollary 3.2.1.1.
Let
o n +2 n n +2 D = (Cn,C )nE;f (=(Cn,C) nE;r)'
Filtered Cochain Complex the filtered cochain complex in
A
399
whose first co-ordinate is
the eochain complex of Example 6, and whose second co-ordinate is the eochain complex of Example 7 with degrees shifted up by +2.
Then
D*
is a filtered coehain complex in
first integrated partial abutment of is also not co-complete.
D*
A,
and the
is not complete and
Therefore by Corollary 3.2.1.1, con-
clusion CD,the first integrated partial abutment of also not Hausdorff and not co-Hausdorff.
D*
is
Section 9 Convergence
Given, say, a conventional bigraded spectral sequence, there are several things that are desirable. (1)
In order, they are
Does the spectral sequence have an "honest" abutment
(in the sense of Definition 1 of section 7)?
Or, at least, a
set of partial abutments with some nice properties? questions are answered in principle:
These
in section 7, if the
spectral sequence comes from a (conventional, bigraded) exact couple, see Theorems 2 and 3 and their Corollaries, and Proposition 4, parts (2) and (3); and in section 8, in the special case that the spectral sequence comes from a filtered cochain complex, see Theorems 1, 1 (2)
0
and 2 and their Corollaries.
Is the abutment (or partial abutments) complete and
co-complete?
This question, also, is answered in the case of
the spectral sequence of an exact couple, in section 7, see Propositions 4, 5 and 6 and their Corollaries and associated Remarks.
For the special case of the spectral sequence of a
filtered cochain complex, the question is answered in Theorems 1, 1
0
,
2 and their Corollaries (see especially Corollaries
3 . 2. 1 . 1, 3. 2 . 1 . 2 and 3. 2. 1 . 3) . It is noted (section 7) that a conventional, bigraded spectral sequence coming from an exact couple has a left defect and a right defect, which can be thought of as obstructions for the 400
Convergence
401
inverse limit abutments and the direct limit abutments, respectively, to be perfect (Definition 5 of section 7).
(In
the category of abelian groups, the right defect is always zero.)
In the case of a filtered cochain complex, section 8, it
is shown that, all of the four in general different exact couples that yield the spectral sequence have the same left and right defects -- and that even a map of filtered cochain complexes that induces an isomorphism along Ei,q induces an isomorphism on the left and right defects, see Proposition 4 of section 8.
Thus, when the spectral sequence comes from a fil-
tered cochain complex, necessary and sufficient conditions to have a reasonable abutment (in the sense of Definiton 1 of section 7) is that these left and right defects are zero, see section 8, Corollary 3.2.1.1 and the Remarks following.
(Again,
in the category of abelian groups, right defects are always zero.) A sufficient condition for a conventional, bigraded exact couple in an abelian category
A (such that denumerable direct
products exist, and such that the functor "denumerable direct product":
AW~~ is exact),
to have a left defect that is zero
(i.e., to have perfect inverse limit abutments), is for the spectral sequence to converge (see Remark 2 following Corollary 4.1 below).
Weaker still, it suffices that the cycles stabilize,
in the sense of Definition 1 below, with no assumptions at all on uniformity of this stabilization. lary 4.1 below.
This is proved in Corol-
Since it is important to know when the left
defect vanishes, this motivates the study of spectral sequences that converge (in the sense of Definition 1.1 below), or that
402
Section 9
at least are such that the cycles stabilize (in the sense of Oefinition 1 below).
These definitions are usually only consid-
ered for conventional bigraded, or perhaps conventional singly graded, spectral sequences.
But, as it is no more difficult
to pose some of these definitions in greater generality, we begin at such a greater level of generality. Proposition
1.
Let
A be an abelian category, let D be an addi-
m m m tive abelian group, let rO be an integer and let (Er,dr,Tr)mED r~rO
be a D-graded spectral sequence starting with the integer rO in the abelian category A (see the beginning of section 4, Example 2 following Definition 1).
r
l
be a fixed integer (A)
Let m E D be a fixed degree, and let
~rO.
Then the following three conditions are equivalent.
(1)
For every integer r
quotient object Em of Em r
tient-object of
(2)
r
Em
rl '
~
r
l
, we have that the sub-
in the abelian category
A is a quo-
l
so that we have a natural epimorphism:
Fix any integer ra such that rO 2 ra 2 r l
(for example, one can take ra integer r
~
=
rO; or rC
=
r l ).
Then for every
r l , we have that the (r-ra)-fold cycles and the
(rl-ra)-fold cycles in Em coincide, ra m
Zr-r' (E r ,) o 0 (3)
(B)
d
m
r
=
Z
(Em) r -r' r' , all r > r l 100
0, for all r
~
r
.
l
In addition, the following three conditions are
equivalent.
Convergence (1°) subquotient subobject, r
For every integer r
object Em of Em r
r
~
403 r
l
, we have that the
in the abelian category
A is a
l
so that we have a natural monomorphism:
>
(2°)
Fix any integer r6 such that rO 2 rO 2 r
= rO; or rO = r l ).
example one can take r6 teger r
~
(for l Then for every in-
r l , we have that the (r-r6)-fold boundaries and the
(r l -r6)-fold boundaries in
E;.
o
coincide,
(Em) r'
o
m-a
d
a
r: E r r
r -+
-+
Em r
is the zero map, where a
r
E D is
E* r
The proof of part (A) is an easy consequence of the definition of a D-graded spectral sequence, see section 4, Example 2 following Definition 1, and is left as an exercise (one can use the Exact Imbedding Theorem, which
[I.A.C.l, to reduce to the case in
A is the category of abelian groups if one wishes, al-
though this is not necessary).
And, of
cou~se,
part (B) follows
from part (A), by passing to the dual category. Defini tion 1.
The hypotheses being as in Proposition 1, if
the three equivalent conditions of part (A), hold (respectively: (B),
(1°),
(1),
(2) and (3),
if the three equivalent conditions of part
(2°) and (3°), hold), then we say that the cycles
(respectively:
boundaries) stabilize in degree m past the inte-
Section 9
404
(The terminology emphasizes condition (2) m m m If (Er,dr"r)mED
(respectively:
is a D-graded spectral sequence in an
r~O
abelian category A, and if m E D is a degree, then we say that the cycles (respectively: there exists an integer r
boundaries) stabilize in degree m iff l
such that the cycles (respectively:
boundaries) stabilize past r Corollary 1.1.
l
.
Let the hypotheses be as in Proposition 1.
Then the following two conditions are equivalent. For every integer r ~ r
(1) of Em r
l
, the subquotient-object E~
is the whole object Em , so that we have a canonical isor
l
l
morphism: Both the cycles and the boundaries stabilize in degree
(2)
m past the integer r , in the sense of Definition 1 above. l Proof:
In fact, condition (1) of Corollary 1.1 is clearly
equivalent to:
condition (1) of Part (A) of Proposition I,
and condition (1
0
)
of part (B) of Proposition I, both holding.
Therefore the Corollary follows from Definition 1. Definition 1.1. dm m) (0) (E m r' r,Tr mEO
Q.E.D.
Let D be an additive abelian group and let be a O-graded spectral sequence starting with
r~rO
the integer rO in the abelian category A.
Let m E D be a degree.
Then we say that the spectral sequence (0) converges in degree
m
iff there exists an integer
rl~rO
two equivalent conditions of Corollary 1.1 hold. then given such an integer r
l
such that the If this is so,
we sometimes say that the spectral
Convergence
405
sequence (0) converges in degree m past the integer r
l
(or,
sometimes, we say that the spectral sequence (0) degenerates in degree m past the integer r ). l The spectral sequence (0)
is said to converge if it converg-
es in degree m, for every degree m E o. Definition 1.2.
The spectral sequence (0)
uniformly if there exists an integer r
l
is said to converge
, independent of m E 0,
such that the spectral sequence (0) converges in degree m past the fixed integer r
l
, for all degrees m E
o.
When this is the
case, then given such an integer r l we often say that the spectral sequence (0) converges uniformly (or, sometines, degenerates uniformly) past the integer r
l
.
The notion, Definition 1.1, of what it means for a
Remark:
spectral sequence to converge does not generalize, beyond the case of a D-graded spectral sequence, to that of a spectral sequence in a general D-graded abelian category.
However, the
next corollary shows that the notion, Definition 1.2, of what it means for a spectral sequence to converge uniformly does so generalize. Corollary 1.2.
Let D be an additive abelian group, let B be a
D-graded abelian category, let rO be an integer and let (E ,d r r rOo
)r>r be a spectral sequence starting with the integer - 0 Let r be an integer ~rO. Then the following six condil ,1
r
tions are equivalent. (1) E
r
For every integer r
is the whole object E l
r
~
r
l
, the subquotient-object Er of
, so that we have a canonical isol
morphism of degree zero, E r "" Er
l
Section 9
406
For every
(I' )
of E
r
For every integer r
is a subobject of E l
r
l
r
~
l r l , the subquotient-object E r
l
Fix any integer rO such that rO
one can take >
r
r l , the subquotient-object E r
~
l
(2)
r
r
is a quotient-object of E
r
(1,0)
of E
integer
rb = rO:
or
rb =
r ). l
~
~
rO
rl
(for example,
Then for every integer
, we have that the (r-rO)-fold cycles and the (rl-rO)-fold
cycles of E , coincide, rO Z
(2
0
all r
,(E,)
r-r O
rO
>
r
l
.
Fix any integer rO such that rO ~ rO ~ r l
)
rO: or rO
one can take rO
=
r )· l
(for example,
Then for every integer
r > r l , we have that the (r-rb)-fold boundaries and the (rl-rb)fold boundaries in E , coincide, rO B
( 3)
Note:
d
I
r-r 0
r
(E
o
all r > r
,)
r0
for all integers r
~
r
l
l
.
.
If the D-graded abelian category B is the category AD
of all D-graded objects in an (ordinary, ungraded) abelian category A (see section 3, Example 1), then the above six equivalent conditions are also equivalent to the condition that, "For the fixed integer r l that the condition (1)
~
r
' we have for all degrees mE D, O
(equivalently:
condition (2)) of
Corollary 1.1 holds. Proof:
By the Exact Imbedding Theorem for D-Graded Abelian
Convergence
407
Categories (section 3, Corollary 5.1), it suffices to prove the Corollary in the case in which B is the category of D-graded abelian groups.
(Alternatively, we can use simply Theorem 5 of
section 3, to reduce to the case in which B is the category AD of all D-graded objects in some (ordinary, ungraded) abelian category A.)
But then, the equivalence of conditions (1'),
(2) and (3) follows from part (A) of Proposition 1; and the equivalence of conditions (1,0), (B) of Proposition 1.
0 (2 ) and (3) follows from part
Since also condition (1)
is clearly
equivalent to conditions (1') and 1,0), we have the equivalence of the six conditions of the Corollary. Finally, if the hypotheses are as in the Note to the Corollary, then clearly condition (1) of Corollary 1.1 is identical to condition (1) of this Corollary, which proves the Note. Q.E.D. Definition 1.2.1.
Let D be an additive abelian group, let
B be a D-graded abelian category, let rO be an integer and let
(0) (Er,dr,Tr)r>r be a spectral sequence starting with the in- 0 teger rO in the D-graded abelian category A. Then we say that the spectral sequence (0) converges uniformly iff there exists an integer r
l
~
rO such that the six equivalent conditions of
Corollary 1.2 above hold. such an integer r
l
If this is the case, then given
, we also say that the spectral sequence (0)
converges uniformly (or degenerates uniformly) past the integer
Then, by the Note to Corollary 1.2, we have that Definitions 1.2 and 1.2.1 agree in the only case in which they both make
sensei i.e., in the case that Definition 1.2 makes sense. Therefore,
Definition 1.2.1 is a generalization of Definition
408
Section 9
1.2, to spectral sequences in arbitrary D-graded categories
B,
where D is any abelian group. Considering section 4, Definitions 3' and 4', and section 4, Remark 2' (2
0
),
(1')
following Corollary 3.1', and conditions (1),
and, respectively,
Corollary 1.2.1.
(2),
(l'o), we deduce immediately
The hypotheses being as in Corollary 1.2, we
have that the six equivalent conditions of Corollary 1.2, and therefore also the condition that lithe spectral sequence converges uniformly past the integer r
l
", are also equivalent to
each of the following conditions: (1 00 )
Eoo exists, and the subquotient-object Eoo of Erl is
the whole object E
(2 00 )
r
, l
Fix any integer ro such that rO
~
rO
~
r
l
.
Then
(E ,) exists, and the sub-objects Z (E ,) and Z ,(E,) of rO 00 rO rl-r O rO E , coincide, rO Z
00
Z
(E 00
(2~)
,) r 0
Fix any integer rO such that rO ~ rO ~ r l .
Then
B (E ,) exists, and the
00 rO E , coincide, rO
B
(E 00
(l~)
E 00 exists,
,) r 0
and the subquotient-object Eoo of E
a quotient-object of Er . 1
r
is l
Convergence E a
409
exists, and the subquotient-object E
subobject of E
r
of E
r
is l
l
The proof of Corollary 1.2.1 also shows (using again section 4, Definitions 3' and 4', and section 4, Remark 2' following Corollary 3.1'), that, Corollary 1.1.1.
Let the hypotheses be as in Proposition 1.
Then (A)
The following two conditions are equivalent, (c)
The cycles stabilize in degree m past the integer
(In other words,
"The three equivalent conditions of
Proposition 1, Part (A), hold.") (2)
Fix any integer rO such that rO
Z (Em,) exists, and the '"
r 0
subobjects Z (Em,) and '" rO
Then co-
incide,
If also E: exists, then the following condition is also equivalent: The
(B)
sub quotient E: of Em r
is a quotient-object l
Also, the following two conditions are equivalent. (b)
integer rl'
The boundaries stabilize in degree m past the (In other words,
"The three equivalent conditions
of Proposition 1, part (B), hold.")
(2~)
Fix any integer rO such that rO :5.. rO :5.. r l ,
B (Em,) exists, and the '" rO
,(Em,) subobjects B (Em,) and B rl-r O rO '" rO
Then
Section 9
410
coincide,
If also E: exists, then the following condition is also equivalent: The
subquotient Ern of Ern r
00
Lemma 2.1.
subobject of Ern
is a
r
l
Let A be an abelian category and let t(p+l)
t (p+2) -+
t
vp +l
be an inverse system in the abelian category the integers. object in
Then let V
A, and let t =
(p-l)
A, indexed by all
p
= (V ) pEl' denote the singly graded (t (p» denote the endomorphism of pEl'
degree -1 of the graded object V.
Suppose, for every integer
p, that there exists an integer r(p)~O, depending on
for all integers r all integers i
>
l
p.
~
r(p)
p, such that
,
Then, for every pair of integers i,p with
1, there exists a positive integer ri,p such that ( 2)
for all integers r > r.
~,p
Note:
In equations (1) and (2), t
r , t i , etc., stand for the
respective iterateS of the endomorphism t of the graded object V (not for the components, t(p) :VP Proof:
-+
vp - l
, p E 1", of t).
By the Exact Imbedding Theorem [I.A.C.], it suffices
Convergence
411
to prove the Lemma in the case in which A is the category of abelian groups.
We do this by induction on i
>
1.
For i = 1, take r. r(p). Having proved the assertion l,p r for the integer i > 1, suppose that r 1 ~ 0 and that x E [(t IV) n i+l p . (Ker t ) ] , 1 . e., tha t x E (trlV)p and ti+lx o. Then rl+l -1 i V)p and t (tx) = O. Hence, if r tx E (t > r. 1-1, then l,pl tx E [~ri,p-IV) n (Ker ti)]p-l, and therefore by equation (2) for all positive integers r we have that tx E tr+lv, say tx tr+ly, for some y E Vp - r . r
=
O.
Also x-tryE
are both
~r(p), then
Then t(x-try)
r
t Iv + t V, so that if also rand r
l
x-try E tr(p)v, and therefore x-try E [(tr(p)V)
n (Ker t)]P.
But then by equation (1), we have that x_try E trV, and therefore x E trV.
Therefore, if we let r'+ r = sup(r. 1 l ,p l,p- 1-1, l then whenever x E [(tri+l,PV) n (Ker ti+l)]p, we have
r(p)),
that x E trv for all integers r
>
r(p), completing the induc-
tion.
Q.E.D. The proof of Lemma 2.1 shows that one can take r. l,p
Remark:
sup(r(p), r(p-l)-1,r(p-2)-2, ... ,r(p-i+l)-i+l), all i,pE2" with i
> 1.
The next definition and Lemma appear in [I.L.].
We re-
produce them here for the sake of completeness of exposition. Definition 2.
Let
A be an abelian category and let
t(p+2) (1)
. .. ~ v P +1
t(p+l) Jp) -----.. v P - - - ?
be an inverse system in the abelian category the integers.
A, indexed by all
Then let V = (V P ) P (i7 denote the singly graded
object in A, and let t = (t (p) )pEt" denote the endomorphism of
Section 9
412
degree -1 of the graded object V.
Then we say that the images
stabilize in the inverse system (1), iff, for every integer p, there exists a positive integer r(p) such that
Example.
In terms of Definition 2, the conclusion of Lemma 2
above can be written, "For every integer p the inverse system:
[Vn(Ker t)]p
is such that the images stabilize." Lemma 2.2.
Let A be an abelian category such that denumerable
direct products exist and such that the functor "denumerable direct product" is exact. gory
A is (P.2)
Assume, in addition, that the cate-
such that, Whenever (A., a .. ). . E is an inverse system in 1 1J 1,J 'l' j::i the category
A indexed
by the integers such that
each a .. is an epimorphism, then the map from the 1J inverse limit: [lim Ai]
-+
AO
i~+'"
is an
epimorphism~*)
(E.g., the category of abelian
groups obeys Axiom (P.2).) Let (*)see Introduction, Chapter 1, section 7.
Convergence t(p+2) (1)
•• ,
t(p+l) Vp + l
--;>
--;,
413
t (p)
vP
t (p-l) Vp - l
_ _;>
--;>
•• ,
be an inverse system in the category A such that the images stabilize.
Then (infinitely t-divisible part of V)
(2)
(t-divisible
part of V), and
o.
(3)
Proof:
For every integer p, choose a positive integer r(p)
as in Definition 2.
Then by equation (2) of Definition 2, we
have that
for all integers r,p such that r
~
r(p).
For a given integer p, choose r any integer such that r
>
sup(r(p),r(p+l)+l).
(trV)p
=
t«tr-IV)p+l)
Then (t-divisible part of VIP t«t-divisible part of V)p+l), and
therefore (5)
t maps
(t-divisible part of V)p+l epimorphically
onto (t-divisible part of VIP , for all integers p. We have that lim (t-divisible part of VIP.
pE ?:
414
Section 9
This latter, by equation (5), is an inverse system in which all the maps are epimorphisms.
By Axiom (P.2), we have that the
natural mapping: lim (t-divisible part of VIP
+
(t-divisible part of
+-
p E7'
is an epimorphism, for all integers PO.
These last two equa-
tions imply conclusion (2) of the Lemma. By ea.
(4), in the inv. sys.
V/(t-div. part), the map
from the(p+r(p))'th term to the p'th term is zero. 11ml (V/ (t-div. part)) = O.
By eq.
11ml (t-divisible part of V)
= O.
Therefore
(2) and Chap. 1, sec. 7, Thm. 2
Therefore
Ij,mlv
= 0,
(3).
proving Q.E.D.
Proposition 3.
Let D be an additive abelian group, let B be a
D-graded abelian category, and let
t
v~/ E
be an exact couple in the D-graded abelian category B (see section 5, Definition 3').
be the
Let
spectral sequence of the exact couple (see section 5,
Definition 5').
Let r
l
be a non-negative integer.
following conditions are equivalent.
Then the
Convergence
(1) teger r
l
The spectral sequence converges uniformly past the in. r
(2)
r
415
n
(t IV)
(Ker t), for all integers
>
If the (t-divisible part of V) exists, then it is equivalent to write: (2",)
n
(t-divisible part of V)
r
(Ker t)= (t IV)
n
(Ker t).
r
[Ker(t 1:V7V)] +tV, for all integers r
~
r
l
.
If the (t-torsion part of V) exists, then it is equivalent to write: (t-torsion part of V) Proof:
+ tV
=
r
[Ker(t
l
:V7V)] + tV.
The hypotheses of Corollary 1.2 hold, with rO = O.
Therefore, by Definition 1.2.1 and Corollary 1.2 above, condition (1) of this Proposition is equivalent to condition (2) of Corollary 1.2, with rO
= rO
o.
But then, by section 5,
Corollary 3.1', equation (lr)' and section 5, Corollary 3.2', equation (lr)' it follows that condition (2) of Corollary 1.2 (with rO
=
rO
Proposition.
=
0) can be rewritten as condition (2) of this
Therefore conditions
are equivalent.
(1) and (2) of the Proposition
By definition of " (t-divisible part of V)", (2)~
if this latter exists, then
(2",).
Similarly (using
section 5, Corollary 3.1', equation (2 ), and section 5, r 0 Corollary 3.2', equation (2 ); and condition (2 ) of Corollary r
1.2), we see likewise that (l)~(20), and that, if the (t-
416
Section 9
torsion part of V) exists, then (2)
~(200)'
Q.E.D.
The "degree by degree" form of Proposition 3, is Corollary 3.1.
A be an
Let D be an additive abelian group, let
(ordinary, ungraded) abelian category and let
t
E
be a D-graded exact couple in the abelian category deg (k) + deg (h) E D and
y
= deg (h).
A.
(Then deg (k)
Let
=
p
p-6
E D.)
Let m E D be any fixed degree, and let r
l
be any fixed
non-negative integer. (A.)
Then the following conditions are equivalent. (1)
integer r
l
The cycles stabilize in degree m past the
. r
[(t lV)
(2)
for all integers r
~
r
l
n (Ker t) 1m+p-y,
.
If the (t-divisible part of V) exists, then it is equivalent to write: (2 00 )
(B.)
[(t-divisible part of V)
n (Ker t) lm+ p - y
Also, the following conditions are equivalent. (1°)
The boundaries stabilize in degree m past the
Convergence integer r
l
417
. r
([Ker(t l :V-+V)] + y tV)m- , for all integers r ~ r
l
.
If the (t-torsion part of V) exists, then it is equivalent to write r
[it-torsion part of V) + tV]m- y
(2~)
([Ker(t 1
V-+V)] + tV) m-y . ~:
Of course in the statement of Corollary 2.1, the
mapping of D-graded objects: "tr" stands for "the with itself r-times"
iterate of t
(and not "the r'th component of t as a map
of D-graded objects" -- this latter does not even make sense, in general, since D is not in general contained in the integers, and therefore a positive integer r need not be a degree, i.e., need not be an element of D). The proof is similar to that of Proposition 3. Remarks.
1.
By Lemma 2.1, and the Remark following, condition
(2) of Proposition 3 is equivalent to: r
(t IV)
n
for all integers r Proof:
(Ker ti), ~
r
l
.
By section 3, Corollary 5.1, the Exact Imbedding Theorem
for D-Graded Abelian Categories, it suffices to prove the assertion in the case that B is the category of D-graded abelian groups.
Then, replacing the D-graded abelian group V
=
d
(V )dED
d
with the (ordinary, ungraded) abelian group V = $ V , it sufdED fices to prove the assertion for an abelian group V.
This
Section 9
418
latter follows from Lemma 2.1 and the Remark following. 2.
It follows that if, under the hypotheses of Proposition
3, we have that the (t-torsion part of V) exists, then condition (2) is equivalent to condition r
(trV) n (t-torsion part of V)
(2' )
part of V), for all integers r 3.
~
(t lV) n (t-torsion
rl ·
Under the hypotheses of Proposition 3, if both the
(t-divisible part) and the (t-torsion part) of V exist, then condition (2') of Remark 3 above, and therefore also condition (2) of Proposition 3, are each equivalent to: (t-divisible part of V) n (t-torsion part of V)
(2~:
r
(t lV) n (t-torsion part of V). 4.
The dual of Remark 3 above, is that under the
hypo-
theses of Proposition 3 above, if both the (t-divisible part) and the (t-torsion part) of V both exist, then (t-divisible part of V) + (t-torsion part of V) r
(Ker t 1) + (t-divisible part of V)
;
otherwise stated,
(2~' )
r
The images of Ker t l
and the (t-torsion part of V)
in V/(t-divisible part) are the same. 5.
Another way of writing the condition,
ition 3, is that: in V/tV."
r
"Ker(t) and Ker(t
rl
(2
0
)
of Propos-
) have the same images
Similarly, condition (2~) of Proposition 3, when it r
makes sense, is equivalent to: "the (t-torsion of V) and Ker t l
Convergence
419
have the same image in V/tV." Let A be an abelian category such that denumerable
Theorem 4:
direct products exist, such that the functor "denumerable direct product" is exact, and such that Axiom (P.2) holds (see Introduction, Chapter 1, section 7).
(E.g., the category of
abelian groups, and also its dual category, obey all of these condi tions . ) Let t
E
be a conventional bigraded exact couple in the abelian category Let (Ep,q dP,q ,p,q) r ' r ' r p,q,rE;r r > rO be the associated conventional bigraded spectral sequence start-
A, starting with some integer rOo
ing with the integer rOo
Suppose that, there exists a fixed
integer n, such that (1)
The cycles stabilize in degree (p,n-p) for all inte-
gers p. Then (2)
(left defect)p,n-p = 0 for all integers p, and there-
fore the n~th inverse limit abutment "R n (as defined in Theorem 2 of section 7) is perfect (as defined in Definition 5 of section 7). Proof:
For simplicity of notation, we first replace the given
420
Section 9
exact couple by an exact couple that is isomorphic by means of a map of bidegree (0,0) and such that the map h of the new exact couple is of bidgree (0,0).
Then by Corollary 3.1,
part (A.), the hypothesis (1) is equivalent to asserting that, for every integer p, there exists an integer r p -> sup (rO'O) such that r
[(t PV) n (Kert)jP,n- p ,
(3) whenever r
> r
p
.
Then by Lemma 2.1 applied to the inverse system
-)-
of section 7, Theorem 2, Note gers i
>
... ,
2, it follows that for all inte-
1, and all integers p, that there exists an integer
r, > 0 such that l,p
whenever r
>
r
, p,l
(In fact, one can take r
, = sup(r,r
p,l
p
p-
1-1, ... ,r
'+l-i+l).) P-l
By the Example following Definition 2, in the inverse system: (4 ) ... +[V n Ker ti+ljP+l,n-p-l + [V n Ker tijP,n-p + p + [V n Ker t 2 jP-i+2,n- p +i-2 + [V n Ker tjP-i+l,n-p+i-l ,
(in which the maps are the restrictions of the appropriate components of t), we have that the images stabilize in the sense of Definition 2.
Therefore, by Lemma 2.2, conclusion (2), it
follows that the (t-divisible part) and the (infinitely tdivisible part) of the inverse system (4 ) coincide. p
In terms
Convergence
421
of the inverse system (6 ) of section 7, Theorem 2, Note 2, n this latter observation is equivalent to the statement that (5
.)
p,l
n (Ker ti)]p,n-p
[(divisible part of V)
n
[(infinitely divisible part of V)
for all integers p,i with i
(5
>
1.
Taking i
1 in equation
.), this implies that p,l (6 ) p
n
[(divisible part of V)
(Ker t)]p,n- p
[(infinitely divisible part of V) for all integers p.
By Remark 1
(Ker t)]p,n- p ,
n
following Definition 5 of
section 7, this latter is equivalent to the conclusion, equation (2), of the Theorem.
Q.E.D.
Remarkl. The proof of Theorem 4 shows, in fact,
that under the
other hypotheses of Theorem 4, the condition (1) of Theorem 4 is equivalent to the assertion, that the
(n+l-a-~
'th
inverse
system: ... -+V
p+l,n-a-B-P
+
1 vp,n+ -a-B-P
+
p-l,n+2-a-B-p V
of section 7, Theorem 2, Note 2, Note 1 to that Theorem, so that
......
(where a, sand rO are as in l-a-S = total degree of k),
obeys the hypotheses of Lemma 2.1.
Or, by Lemma 2.1 and the
Example following Definition 2, we have that condition (1) of Theorem 4 is also equivalent to the assertion that, for every integer p, the inverse system:
Section 9
422
... -+[V n (Ker t [V
3
p+2,n-l-a-rl-p )]
+
n (Ker t 2 )] p+l,n-a-~-p
+[V n(Ker t)]p,n+l-a-B-p
is such that the images stabilize in the sense of Definition 2 above. Remark 2. If one replaces the principle hypothesis of Theorem 4, that "the cycles stabilize," by the much more stringent hypotheses, that "conditions (1) and (2) of Proposition 5.1 below hold," then one can eliminate all hypotheses on the abelian category A and still obtain the conclusion of Theorem 4. Proof:
As in the proof of Theorem 4, replace the given exact
couple with one that is isomorphic through an isomorphism of bidegree (0,0), such that the new exact couple is such that the map k is of bidegree (0,0).
Then, as in the proof of Propos-
ition 5.1 below, we see that conditions (1) and (2) of Proposition 5.1 imply that, there exists an integer r
l
, such that for
the rl'th derived couple
of the given exact couple, we have that the mappings tP+l,n-p-l: vP+l,n-p-l r
l
r
l
Convergence are isomorphisms for p
~
PO + 1.
But then clearly ) jP,n- p
[(t-divisible part of V
(1)
r
=
423
l
[(infinitely t-divisible part of V
r
Since (v
)jP,n-p l
,E ,t ,h ,k ) is the r 'th rl r r r 1 r l l l l 1 = t V, derived couple of the given exact couple, we have that V for all integers p.
r
r
l
and therefore (2)
(t-divisible part of V) = (t-divisible part of V
r
), l
(infinitely t-divisible part of V)
= Equations
(infinitely t-divisible part of V
r
) l
(1) and (2) imply that
[(t-divisible part of V)jP,n- p
[(infinitely t-divisible
part of V)jP,n-p
for all integers p.
Intersecting this latter equation with
Ker(t), we obtain that the (p,n-p) 'th object of the left defect is zero. Corollary 4.1.
Q.E.D. Let A be an abelian category such that denumer-
able direct products exist, such that the functor "denumerable direct product": holds.
W
A
'IJV>
A is exact and such that Axiom (P.2)
(See Introduction, Chapter 1, section 7.
E.g., the
category of abelian groups, and also its dual category, obey these conditions.)
Suppose that we have a conventional bi-
graded exact couple in the abelian category A, such that the associated spectral sequence is such that
424
Section 9 For every pair of integers p,q, the cycles in degree
(1)
(No condition of uniformity is assumed.)
(p,q) stabilize.
Then the left defect of the exact couple is zero, and therefore the inverse limit abutments:
n
"H , n E'l' , of the exact couple
are all perfect (in the sense of Definition 5 of section 7). Note:
If one replaces the principle hypothesis (1) of
Corollary 4.1, that "the
cycles stabilize," by the much more
stringent hypothesis, that "For every integer n, condition (1) of Proposition 5.1 below holds," then one can eliminate all hypotheses on the abelian category A, and we still obtain all of the conclusions of Corollary 4.1. Proof:
Follows immediately from Theorem 4.
immediately from Corollary 4.2.
Remark 2
The Note follows
following Theorem 4.
Assume the hypotheses of Corollary 4.1.
Then
for all integers p and n, we have that liml [V
n
(Ker ti)jP-i+l,n-p+i-l
o.
+-
i>l Note:
The proof of Corollary 4.2 shows that, under the weaker
hypotheses of Theorem 4, we have that liml [V
n (Ker ti, jP-i+l,n-
itl where n is as in Theorem 4 and 1 -a-I) is the total degree of k (notation being as in section 7, Theorem 2, Note 1). Proof:
Follows immediately from Remark 1 following Theorem
4 and from Lemma 2.2, conclusion (3). Example 1.
Let A be an abelian category as in Theorem 4, and
Convergence
425
suppose that we have a conventional bigraded spectral sequence (EP,q dP,q ,p,q) that comes from a conventional bigraded r 'r 'r r ~ rO exact couple. Suppose that (1)
We have an integer n, such that there exists an in-
teger PO such that, whenever p ~ PO' we have that E~~n+l-p (or, weaker, such that there exist integers PO,r suc h that EP,n+l-p = 0 wh enever p r
there exist integers PO,r whenever p
~
~
l
Po and r
~
l
with r
r l ).
with r
PO; or, wea k er s tOll 1
l ,
~
0
rO
th a t
~ rO such that d~-r,n-p+r = 0
l
Then, by Theorem 1, we have that
the n' th inverse limit abutment "H perfect.
l
=
n
of .the exact couple is
(Since then obviously for all inegers p, the cycles
stabilize in degree (p,n-p).) Exam~.
Suppose, given a conventional bigraded spectral
sequence starting with the integer rO that comes from a conventional bigraded exact couple in an arbitrary abelian category
A, that the spectral sequence is such that, (1)
For every integer n, there exists an integer Po =
PO(n), and an integer r
l
=
rl(n)
~
r O' such that, whenever
p ~ po(n), we have E~~7~f = 0 (resp.: such that Axiom (P.2) holds and such that whenever p
~
PO(n)
, r
~
rl(n), we have
dP-r,n-p+r = 0) • Then the hypotheses of the Note to Corollary r
4.1 (resp.: of Corollary 4.1) are satisfied and therefore the left defect vanishes; so that the inverse limit abutments, n "H , n E7 , are all perfect. Remarks.
1.
Graphically, a conventional bigraded spectral
sequence obeys the condition of Example 2 above, if and only if along every line of slope -1 in the diagram,
426
Section 9 n=l
n=O
n =-1
' "E -32 r l
' " E r-22 1
"\. E-12 r l
n=2 ' " E02 r l
ceeding in the indicated direction (to the bottom right), we eventually reach a spot (in general varying from line to line) after which all of the terms on that particular line are zero. (The condition in Example 2 reads: "such that all d**'s that r
terminate in a spot on the n'th line, past (i.e., to the bottom right of)
(PO(n),n-PO(n)), and have r
~
rl(n), are zero maps.")
E.g, this is so for an upper half plane spectral sequence (i.e., one confined to the region {(p,q): q
~
a}), or a first
or third quadrant spectral sequence, etc. 2.
An
obvious
case in which the spectral sequence obeys
the condition (1) of Corollary 4.1, is if the spectral sequence converges. 3.
However, it is not difficult to construct a convention-
aI, bigraded exact couple (in fact, even one coming from a double complex, see section 10 below) in the category of abelian
Convergence
427
groups such that the cycles stabilize, but such that the boundaries do not stabilize in degree (p,q) for any pair of integers (p,q).
(Therefore, Corollary 4.1 is "better" than Re-
mark 2 above.) Proposition 5.
Let
A be an abelian category such that denumer-
able direct products and denumerable direct sums exist, such that the functor "denumerable direct product" is exact and such that Axiom (P.2) holds (see Introduction, Chapter 1, section 7). Let C* be a filtered cochain complex in the abelian category and let (EP,q dP,q TP,q) r'r'r r>l n be a fixed integer. (1)
be the spectral sequence.
A,
Let
Suppose that
For infinitely many positive integers p, the filtered
object Hn(co-comp(C*)/F(co-comp C*» p
is co-Hausdorff (this
condition is automatically satisfied if, e.g., the functor "denumerable direct limit" in the abelian category
A is exact),
and that (2)
For every pair of integers p,q such that p+q = n,
there exists a positive integer B(p,q) such that, for every integer i ~ 0, we have that dP-i,q+i r
o
whenever r > B(p,q)+i.
Then the (n+l) ' s t integrated partial abutment, Hn+l, as defined in section 8, is complete. Notes:
1.
If one deletes the hypothesis (1) in the statement
of the Proposition, then the proof shows that there is a canonical isomorphism in the category (3)
A,
G+oo(H n + l ): 11ml (G_oo(Hn«co-comp C*YFp(co-comp C*}»}. p++oo
428
Section 9
If one assumes that the functor "denumerable direct sum" is exact, then G_oo(Hn«co-comp C*)/F (co-comp C*))) p
n (H + l (F _p' C*/
F C*)). p
Therefore, in this case, equation (3) can be rewritten: n liml H + l (F C*/F C*). p' :::+00 _pi p
(3 ')
(of course, if either denumerable inverse limits or denumerable direct limits are exact, then the object (3')
2.
is zero.)
Condition (1) of the Proposition holds, if there exists
n n an integer PO such that F C = F C for all integers p ~ Po p Po n (i.e., if C is "co-discrete but not co-Hausdorff"). Proof:
Replacing C* by the completion of its co-completion if
necessary, we can assume that for all integers n.
cn
is complete and co-complete,
Let
o
E
be the dual exact couple of the filtered cochain complex C*, as defined in section 8, Theorem 1°. vp,q = HP+q(C*/Fp+1C*), for all integers p and q, and the map o
k is of bidegree (0,0). Fix integers nand p.
Then the hypotheses imply that the
Convergence
429
cycles stabilize at the bidegree (p-i,n+i-p) past the integer ro(p-i)
= B(p,n-p)+i.
Therefore, by Remark 1
following Theorem 4 we have, for every integer i
> 1, that the
inverse system:
is such that the images stabilize in the sense of Definition 2. In fact, by the Remark following Lemma 1.2, we have, more ~
precisely, for every integer i
whenever r
>
r. , where r. = sup(rO(p), r (p-l)-l,r (p-2)-2, l,p l,p O O
... ,rO (p-i+l) -i+l). that r. l,p
> 1.
of t
= B (p,n-p) +i,
it follows
1.
>
Let B
=
B(p,n-p)
=
r. , all integers l,p
Then equation (1) can be rewritten, that for all inte-
gers i,r with i r
Since rO (p-i)
B(p,n-p), for all integers i, and is therefore
independent of i i
1, that
>
1 and r
>
B
=
B(p,n-p), that the restriction
is an epimorphism:
o
By definition of nt-torsion part," see section 5, Definition 1', the supremum of the increasing sequence of subobjects, i > 1, of vP+r,n-p-r on the left side of equation (2) is the (t-torsion part of V)p+r,n-p-r.
We have likewise that the
supremum of the increasing sequence of subobjects, i
(tB V)p,n-p
~
1, of
on the right side of equation (2) is the (t-torsion
Section 9
430
t
part of B V). Therefore, by section 2, Lemma preceeding Theorem r 3, part (2) applied to the map t Or
have that the map induced by t , o
(t-torsion part of
( 3)
0
V)
p+r n-p-r ,
~
0 0B (t-torsion part of (t
V) )p,n-p , is an epimorphism, whenever r2:.B=B(p,n-p). Taking r=B in the epimorphism (3), we have therefore that ° ° p+B , n-p-B ) t°B ((t-torsion part of V) (tB V»p,n-p .
(4)
o
(t-torsion part of
Substituting equation (4) into equation (3), we obtain that, whenever r > B = B(p,n-p), then we have that the mapping inducr ed by t is an epimorphism (t-torsion part of V)p+r,n-p-r ~ tB((t-torsion
(5)
part of V)p+B,n-p-B) For the fixed integer n, this being true for all integers p, it follows that the inverse system: V)p,n-p)
° ((t-torsion part of
is such that the images stabilize in the sense of
pEZi"
Definition 2.
Therefore, by Lemma 2.2, conclusion (3), we
have that liml (t-torsion part of V)p,n-p
(6)
..-
o •
p++oo
However, since vp,n-p = Hn(C*/Fp+1C*), and the mapping
t :
vp,n-p
+
vp-l,n-p+l are the maps on cohomology induced by
the natural epimorphismsl from the exact sequence: •••
+
°i Hn(Fp_i+1C*/Fp+1C*) + Hn(C*/Fp+1C*)~ n ~ H (C* /F p-~. +lC*) + •••
Convergence we have that, for every integer i in V)p,n-
p
=
(see section
~ 0, that (precise ti-torsion
Im(Hn(Fp_i+lC*/Fp+lC*)
a,
431
+
Hn(C*/Fp+lC*)).
Proposition 3), this latter is the (p-i+l) 'st
filtered piece of Hn(C*/Fp+lC*).
Therefore
(precise ti-torsion in V)p,n-p
(7)
~
for all integers i
O.
=
F
.
p-~+l
Hn(C*/F
Hn(C*/F Hn(C*/F
p+l p+l
Therefore the supremum of the
C*) on the right of equation (7) C*)
C*) p+l'
By hypothesis (1) of the Proposition,
for infinitely many positive integers p, Hn(C*/Fp+lC*) co-Hausdorff.
But
is
subobjects of is all of
Therefore the supremum of the sub-
objects on the left of equation (7) are all of vp,n-p; or, equivalently, (t-torsion part of V)p,n- p for infinitely many positive integers p.
substituting into
equation (6) yields
o . But by section
a,
Corollary 3.2.1, the group on the left of this
equation is G~n+l(c*). (see section
a,
Therefore Hn+l(C*) is Hausdorff.
Since
Corollary 3.2.1) Hn+l(C*) is also "complete but
not Hausdorff", it follows that Hn + l
= Hn+l(C*)
is complete.
(The fact, observed parenthetically above, that hypothesis (1) of the Proposition holds if the functor "denumerable direct limit" is exact, follows from section Proof of Note 1:
a,
Corollary 3.2.1.3.)
We establish equations (6) and (7) of the
above proof as before.
Passing to the supremum over i
in eq.(7),
Section 9
432
(t-torsion part of V)p,n- p
we have that,
Hn(C*/F
F -00
p+l
C*)
Or; otherwise stated, that we have a short exact sequence: (8)
o
o
-+ (t-torsion part of
0
p n-p
V)'
->-
n H (C*/Fp+lC*)
-+ G Hn(C*/F p +lC*) -+ 0 . -00
is right passing to "liml", and using the fact that "liml" + p-++oo p-++ exact, this implies that we have a natural isomorphism: 00
By section 8, Corollary 3.2.1, the left side of this equation is canonically isomorphic to G+ooHn+l(C*), proving equation (3) of the Note.
The rest of the Note follows from section 8, the
dual of Corollary 3.2.1. Proof of Note 2:
The condition of Note 2 is equivalent to asserting that co-comp(C n ) is co-discrete. Therefore, cocomp (Cn)/Fp (co-compC n ) is co-discrete for all integers p, and therefore Hn(CO-Comp(C*)/Fp(CO-Comp C*)) is co-discrete, and a fortiori co-Hausdorff, for all integers p. Proposition 5.1.
Q.E.D.
Let A be an abelian category such that de-
numerable direct products exist and such that the functor "denumerable direct product":
AW"''''>A is exact.
Let C* be a
filtered cochain complex in A such that co-comp(C*) exists (condition automatically satisfied if denumerable direct sums exist in A), and let n be a fixed integer.
Suppose in addition
that there exists an integer PO and an integer r (1)
o whenever
p
>
PO.
l
~
I such that
Convergence
433
Assume in addition that either Axiom (P.2) holds, or that we can choose the integers PO,r , such that l hypothesis (1) above, and also the following condition, hold: (2)
EP,n-p-l r = 0 whenever p ?.PO . l
n Then the n'th integerated partial abutment H is complete. Proof: As in the proof of Proposition 5, replacing C* with (co-comp C*)' if necessary, we can and do assume that C* is complete and co-complete, and we then once again study the dual exact couple of C*.
n As before, we have that H is "complete but
not Hausdorff" and that
Since also Vp,n-p-l
Hn-1(C*/Fp+1C*), to prove the Proposition
it is necessary and sufficient to prove that, in the dual exact couple of C*, we have that
Let
Section 9
434
be the (r-l) 'st derived couple of a dual exact couple of C*, o
~
for all integers r
1.
V
r
tr-lv, and therefore for r
> 1
and for all integers p we have the short exact sequences of bi-
A,
graded objects in (3 )
o ~
(precise t-torsion part of °p-l,n-p
~ vr+l
-+
Vr )p,n-p-l
0
These sequences, for r fixed and all p, are a short exact sequence of
A.
~-indexed
inverse systems in the abelian category
The leftmost inverse system is such that all of the maps are
zero, and therefore has liml zero. -<-
sequences (3)
Throwing the short exact
through the functor "l1ml", and using the fact
that liml is right exact, it follows that -<-
(4)
A portion of the r'th derived couple is the exact sequence (4.1)
v P +l,n-p-2 __________~) vp,n-p-l r
r
\
I
EP +l,n-p-2
EP+l,n-p-l
r
r
Therefore, by hypothesis (1) of the Proposition, we have that the mappings: (4.2)
are epimorphisms whenever r
> r
l , p
~
PO - 1 .
Therefore, if Axiom (P.2) holds (see Introduction, Chapter 1,
Convergence
435
section 7), liml ~p,n-p-l
(5)
.... p ...+oo
0, whenever r
r
>
r
l
.
(This also follows, of course, from Lemma 2.1.) On the other hand, if hypothesis (2) of the Proposition holds, then from the exact sequence (4.1) we deduce that the °p+l n-p-2 0p n-p-l V' ... V ' are monomorphisms whenever
mappings: r
>
r
~
r , p l (4.3)
r
PO-l.
This, and equations (4.2), imply that,
The mappings:
~p+l,n-p-2 ... ~p,n-p-l are
r
isomorphisms for r
r ~
rl , p
~
PO - 1 ;
and therefore, once again, we obtain equation (5), whenever r > r
l
holds.
Therefore, in all cases, we have that equation (5)
.
, equation (4) for 1 ~ r ~ rl-l l vQp,n-p . imply equatlon (2). Q.E.D.
Equation (5) for r = r
Op,n-p and the fact that V1 Example 3.
Suppose that we have an abelian category A such
that denumerable direct products exist and such that the functor "denumerable direct product" is exact.
Suppose that
we are given a filtered cochain complex C* (such that co-comp C* exists), and such that, for every integer n, there exists po(n) and an integer r
an integer PO
all the terms EP,q r
l
rl(n)
> 1 such that,
in rl'st part of the spectral sequence
l
that lie on the bottom right half line: are zero.
=
p + q
=
n, p
~
PO(n)
Then condition (1) of Proposition 5.1 holds for all
integers n (and therfore also condition (2) of Proposition 5.1 holds for all integers n + 1, i.e., for all integers n). But then by Proposition 5.1, we have that the integrated
Section 9
436
partial abutments Hn are all complete for all nE1.
And also
by Example 2 above, we have that the left defect of (all four of the exact couples) of the spectral sequence is zero. Remarks.
1.
Condition (1) of Proposition 5.1 for the integer
n implies condition (2) of Proposition 5 for both the integers n-l and n.
2.
Condition (2) of Proposition 5, or condition (1) of
Proposition 5.1, for all integers n, implies that the cycles stabilize.
(Neither condition for all integers n in general
implies that the spectral sequence converges.)
Condition (2)
of Proposition 5 for all integers n can be thought of as being a condition that the cycles should stabilize "somewhat uniformly." 3.
Let n be a fixed integer, and let
tegers such that PO + qo
=
n.
(p~qO)
be fixed in-
Then condition (2) of Proposition
5, for the given fixed integer n, is equivalent to asserting that:
"The cycles stabilize
at
all spots on the line p + q
n, and the condition in (2) holds for the specific pair
(po,qO)."
Yet another way of writing condition (2) of Proposition 5 is to say that, conditions (2.1) and (2.2) below both hold:
(2.1)
The cycles stabilize, and
(2.2)
There exists a pair of integers (po,qO) such that Po + qo = n and such that the condition in (2) of Proposition 5 holds for the pair (po,qO)
This latter condition, It states that,
.
(2.2), can be expressed graphically.
437
Convergence
\
A
B
\
p
p + q
=
+
n + 1
q
n
"there exist spots A and B, on the line, p + q = nand p + q = n + 1, respectively, such that, given any point 'to the upper left' of A on the line p + q = n and any point' to the lower right' of B on the line p + q = n + 1, the differential(*) connecting them is zero."
From this point of view, it is
clear that condition (2.2) is self-dual, with nand n + 1 interchanging.
We call a spectral sequence that obeys this condition
(*)If A = (Pl,ql)' then (pi,qi) is on the same line p + q = n as A and is "to the upper left" iff pi + qi = Pl + ql (=n), and pi
<
Pl'
Similarly, if B
line as B and "to the lower right" iff pi + and pi
~
P2'
qi
= P2 +q2 (=n+l),
The condition that "the differential connecting
the spots (pi ,qil and (pi,qi) is zero", of course means that the p' q' pi,qi pi,qi ->- E 2, 2 is zero (if mapping d 'E pi-pi ~ rO; otherwise , p'-p" p'-p' pi-pi 2 1 2 1 ' q'" P l' 1 . the condition of "vanishing of d, ,~s taken to be vacuous.)
P2- P l
Section 9
438
(2.2) for all integers n, one that is semi-stable.
Semi-
stability does not imply, in general, either that the cycles stabilize or that the boundaries stabilize. Thus, condition (2) of Proposition 5 holding for all integers n, is equivalent to the statement that, "The cycles stabilize, and the spectral sequence is semi-stable." 4. category
The hypothesis, in Proposition 5, that "The abelian
A is such that denumerable direct sums exist," can be
replaced by the weaker hypothesis, that "co-comp C* exists." The most important case is when the abelian category the category of abelian groups.
A is
Then the functor "denumerable
direct limit" is exact and Axiom (P.2) holds, and therefore, by Remark 1 above, Proposition 5 is a better theorem than Proposition 5.1.
Perhaps this should be summarized as a Corollary.
Corollary 5.2.
Let
A be
an abelian category such that denumer-
able direct products and denumerable direct sums exist, such that Axiom (P.2) holds and such that the functor "denumerable direct limit" is exact.
Let C* be a filtered cochain complex in
A, and let n be an integer.
Suppose that
(2) for every pair of integers (p,q) such that p + q
=
n,
there exists a positive integer B(p,q) such that, for every integer i ~ 0, we have that dP-i,q+i = 0 whenr
ever r
~
B(p,q)+i.
Then the filtered object, the (n+l) 'st integrated partial abutment Hn + l complete, and
= Hn+l(cO-comp(c*'))
is both complete and co-
Convergence Proof:
439
By Proposition 5 we know that Hn is complete.
Theorem 4, we have that (left defect)p,n-p p.
=
By
0 for all integers
The remainder follows from section 8, Corollary 3.2.1.3.
Remark 1.
Suppose that we have the hypotheses of Example 1
following Corollary 4.2, and that the exact couple in Example 1 comes from a filtered cochain complex C*, such that the cocompletion of C* exists.
Then the hypotheses of Proposition 5
are satisfied, and therefore (by Proposition 5) the (n+l) 'st n l integrated partial abutment H + is complete, and (by Theorem 4) the (p,n-p) 'th object of the left defect is zero. If the abelian category A is such that denumerable direct sums exist and such that the functor "denumerable direct limit" is exact, then by section 8, Corollary 3.2.1.3, these conclusions can be sharpened to read:
That the (n+l) 'st integrated
n l partial abutment H + is both complete and co-complete; and n that the n'th integrated partial abutment H is such that G (H n ) ~ p
EP,n- p , for all integers p. '"
Therefore, in this case,
if the hypotheses of Example 1 hold for all integers n, then the integrated partial abutments Hn, n E~
are an abutment in
the sense of section 7, Definition 1, and are complete and co-complete. 2.
Suppose that we have the hypotheses of Example 3 follow-
ing Proposition 5.1.
Then we have observed in Example 3 that
the integrated partial abutments Hn, n E~, are complete; and also that the left defect of (all four exact couples) of the spectral sequence is zero. If in addition the abelian category A is such that denumerable direct sums exist and such that the functor "denumerable
440
Section 9
direct limit" is exact, then by section 8, Corollary 3.2.1.3, these conclusions can be sharpened to read:
That the integ-
n rated partial abutments H , n E~, are both complete and cocomplete, and are an abutment for the spectral sequence, in the sense of section 7, Definition 1.
Section 10 Some Examples
Example 1.
The Spectral Sequences of a Double Complex
Theorem 1.
Let A be an abelian category and let C**
(Cp,q, 3~i;0)' 3~O;l)) (p,q)E.". Xi?
=
be a (whole plane) double com-
plex in A (see section 3, Example 3).
Then there is induced a
conventional, bigraded spectral sequence (EP,q dP,q TP,q) r'r'r r>O starting with the integer zero, such that EP,q r
cp,q
EP,q
Hq(C P , *) ,
1
and
Proof:
,
HP ( (Hq(C i , * )) i E {')
EP,q 2
Case 1.
First, assume that the abelian category A has
denumerable direct sums.
Then define
Following notations as in [P.P.W.C.), we then define 3n :C n
+
c n + l , for all integers n, by requiring that
nl p,q C
3
=
(' l' ) p,q lnc USlon p+l,q 03(1,0)
for all integers p,q such that p + q
441
n.
Then C*
Section 10
442 is an (ordinary,
~-indexed,
the abelian category
A.
singly graded) cochain complex in
Define
n Then F Cn is a sub-object of C , and
for all integers p,n.
p
n Therefore (F C ) p
a filtered object with decreasing filtration. that dn(FpC n ) (F C*) p
p
E
'l'
C
p
E.". v
is
It is immediate
n l FpC + , for all integers n,p.
Therefore C*
=
is a filtered cochain complex.
We have that (2)
and that these isomorphisms, for a fixed integer p and all integers n, make the n'th coboundary of the cochain complex n p n-p Gp(c*) correspond to (-1 ) a(b,l)
Therefore the isomorphism
(2) induces, by passing to the subquotients, an isomorphism, (3) for all integers nand p. The spectral sequence of the filtered cochain complex (1) (see section 8, Theorem 1) is such that H
n
(G
p
(C*»
Therefore, if we define EPo,q
=
cp,q and dP,q
o
=
a p,q
(0,1) ,
then
the spectral sequence of the filtered cochain complex C*, so extended, has the desired properties. Remark:
Tracing through the construction, it is easy to see that
for r > 1, dP,q:EP,q r r
+
EP+r,q-r+l is induced by the inverser
Some Examples
443
composite relation: (,p+r-l ,q-r+l) -1 (,p+l ,q-l) ( ,p+r-l,q-r+l) 0(1,0) 0 0(0,1) 0· •• 0 0(1,0) p+l,q-l -1 o(d(O,l)
)
p,q
0(3(1,0))
by passing to the subquotients. Case 2. of
General case.
Then let AD be a full exact subcategory
A that is a set and that contains the objects cp,q for all
integers p,q, and let F be an exact imbedding from AD into an abelian category B such that denumerable direct sums of objects exist (e.g., by the Exact Imbedding Theorem [I.A.C.], one can take B
=
the category of abelian groups).
Then by Case 1 we
have the spectral sequence of the double complex F(C**) the category B.
in
By induction on r, I claim that EP,q dP,q are
r
in the image of F, r > O.
'r
and dP,q
Since
°
F(d~O;l))' we have that E~,q and
are in the image of F,
for all p,q E ~
If r _> 1, then since EP,q = Ker(dP,q)/ r+l r Im(dP-r,q+r-l), and by the above Remark dP,q is induced by the r
r
image under F of an additive relation in AD from cp,q into cp+r,q-r+l, it follows by the inductive assumption that E~~i and d~:i are in the image of F, completing the induction. Therefore the spectral sequence of the double complex F(C**) in the abelian category B is the image under F of a uniquely determined spectral sequence in [LA.C.l,
it follows
A.
Using the Introduction to
(again by induction on r
~
0) that the
spectral sequence thus defined in the abelian category
A is
independent, up to a canonical isomorphism, of the abelian category B closed under denumerable direct sums and of the exact imbedding: A'VU> B
chosen.
Q.E.D.
444
Section 10 For the rest of this Example, we will assume for simplicity
of statements that the abelian category
A is
closed under
denumerable direct sums and under denumerable direct products of objects.
The filtered cochain complex C* = (FpC*)pEQ' intro-
duced in the proof of Theorem 1 is the traditional one.
It
is co-complete and Hausdorff, but in general is not complete. Its completion is the filtere (4)
Cn"
=(
ID cP,q) p+q=n p,::O
cochain complex C* , where Ell (
II
C
p+q=n
p,q) ,
all integers
n.
, p >0
By the results of section 8, the "best possible hope" for an abutment for the spectral sequence in Theorem 1 are the integrated partial abutments Hn, n ~ 7
, which are by the definition
the cohomology of the filtered cochain complex C*", (5)
Hn = Hn(C*"), all integers n.
Also, by section 8, the spectral sequence of the double complex has a left defect, which is a quotient of E"" = (E:,q) (p,q~ and a right defect, which is a subobject of E",,'
xi'!
(If "denumer-
able direct limit" is exact, then the right defect is zero; see section 7.) By Corollary 1.1 of section 8, we have a set of partial abutments for the spectral sequence of the double complex C**, which is by definition the partial abutments of the exact couple of the filtered cochain complex (F p C*)PE7' direct limit abutments are
(6)
Explicitly, the
Some Examples
445
and (7)
n Since the filtration on C is co-complete for all integers n, if the functor "denumerable direct limit" is exact; by section 8, Corollary 1.3, equation (6) then simplifies to: (6' )
The objects on the right of equation (6') are called by some people the "total cohomology of the double complex C**." Remark:
The traditional filtered cochain complex used to con-
struct the spectral sequence in Theorem 1 is C*. noted, c*" is actually more natural.
As we have
There is one "worst"
possible choice, worse even than the traditional one; namely, the filtered cochain complex 0*, where (7.0)
-~
n D - p+q=n II cp,q)e ( p+q=n i
P20
n E 'F
p>O
with the analogously defined coboundaries and filtration. in general neither complete nor co-complete. 0* is """
.
C*, co-comp(O* ) = C*.
0* is
co-comp(o*)
yet another filtered cochain
complex that, like the traditional C* (= co-comp 0*), is "intermediately bad"; it is the dual construction of the traditional. (7.1)
Explicitly, 0*" is determined by Dn "::
II Cp , q all integers n. p+q=n '
By section 8 the "worst possible" cochain complex 0** gives
446
Section 10
rise to four exact couples,
(all having the same spectral
sequence,namely the spectral sequence of Theorem 1), o 0 co-comp(2 )---> (2
1'1
)~(2)-7(2
)
By results of section 8, the exact couple (2)
is isomorphic to
the traditional exact couple of the traditional C* Similarly, the exact couple (2 act couple of 0*1'1.
0
= co-comp(O*).
is isomorphic to the dual ex-
)
The partial abutments of this dual exact
couple are
lim -+ p-++oo
(7 )
Hn(O*/F
-p-l
0*)
and (8)
where IT
p'
cP
',n-p'
< p
(As usual with the partial abutments coming from the dual exact couple of a filtered cochain complex, the dual inverse limit abutments are more interesting than the dual direct limit abutments.)
If the functor "denumerable direct limit" is exact,
then since 0* is co-complete,
(7' )
0, all integers n.
Therefore, in this case, by section 8, it follows that the o n filtered objects "H , n
E 7 , of equation (8), the inverse li-
mit abutments of the dual exact couple of 0*, must have the
Some Examples
447
same associated graded as the integrated partial abutments Hn , n E? , of equation (5); and therefore in this case that (8')
n
F_oo("H )
~ Hnt", all integers n.
If "denumerable direct product" is exact, then whether "denumerable direct limit" is exact or not, we have that the cohomology Hn(O*A) of the (product) cochain complex O*A, equation (7.1), for its natural filtration, is "complete but not HausTherefore, if "denumerable direct limit" is exact, then F -00 Hn(O*A)/G +00 Hn(O*A) : co-comp (HnA) , all integers n, as complete, co-complete filtered objects. Let us now assume also that the abelian category A obeys Axiom (P.2)
(see Introduction, Chap. I, sec. 7), or else that the
double complex C** is such that conditions (1) and (2) of section 9, Proposition 5.1, hold. By Corollary 4.1 of section 9, if the spectral sequence is such that the cycles stabilize, then the left defects are all zero.
(Therefore, in this case, if also the functor "de-
numerable direct limit" is exact, then the integrated partial abutments are an "honest" abutment for the spectral sequence.) By Prop. 5.1, sec. 9, this is so--that is, the left defect is zero -- (whether or not (P.2) holds), for example if the double complex C** vanishes outside of a region R, such that, for every integer n, the line:
p+q
n is such that there exists
an integer PO' such that the half line {(p,q) :p+q = n,
p~O}'
to the bottom right of the spot (PO,n-PO)' is entirely outside the region R (or, weaker, if there is such a region R such that,
Section 10
448
for every integer n, there exists an integer r = r(n), such that for every pair (p,q) of integers not in R, with p+q=n, we have EP,q = 0). r
For example, this is so if the double complex
is first quadrant; third quadrant; second quadranc upper halfplane; or, more generally, vanishing in the fourth quadrant. Also, by e.g. section 9, Proposition 5.1, if the double complex C** is confined to such a region R (or, weaker, if there is such a region R such that, for every integer n there exists an integer r(n)
>
0 such that EP,q = 0 for all p,q r(n)
such that p + q = nand (p,q) is not in R), then also the integrated partial abutments are complete.
(Proposition 5 of
section 9 gives a more general such statement when Axiom (P.2) holds).
When this is so, and the functor "denumerable direct
limit" is exact, then the integrated partial abutments Hn, nEll', are therefore a complete and co-complete abutment for the spectral sequence.
And if the spectral sequence is confined
to such a region (resp.:
to such a region that obeys the in-
dicated hypotheses and dual hypotheses) then also the integrated partial abutments are discrete (resp.: finite), since EP,q '" vanishes outside the region. Example 1.1.
If the double complex C** vanishes outside of a
region R such that every line
p + q =' n intersects that region
in only finitely many terms (--or, by section 9, Proposition 5, if say Axiom (P.2) holds and either denumerable direct limit or denumerable inverse limit is exact, and if there is such a region R such that, for every integer
~
there exists an integer
B(n) such that for all (p,q) not in R such that p + q = n we have that EP,q + ( ) = 0 -- or, by section 9, B(n) sup p,q --
Some Examples
449
Proposition 5.1, if there is such a region R such that, for every integer n, there exists an integer rl(n) EP,q rl(n) p + q
= =
>
0 such that
0 for all pairs of integers (p,q) not in R such that
n --) then by the above, the integrated partial abutn E ~ , are an abutment, and each H has a finite fil-
ments Hn, n tration.
Example 1.1.1. If the double complex C** vanishes outside of a region R as in Example 1.1, then the reader will verify that the filtered cochain complexes C*, 0*, C*A, D*A discussed in a Remark above all coincide; and therefore the four exact couples collapse to two, co-comp(2
0
)
=
(2
0
),
and (2)
=
(2 A).
The in-
tegrated partial abutments Hn, equation (5), then also coincide with the direct limit abutments 'Hn, equation (6), and the dual
On
inverse limit abutments "H , equation (8), for all integers n; and each has a finite filtration (and the inverse limit abutments "H n and the dual direct limit abutments dentically zero, n E
~
,~n are then
i-
.)
Two important special cases of Example 1.1.1 are first quadrant double complexes and third quadrant double complexes (the latter can be re-interpreted as "first quadrant homological double complexes" by the indexing convention C
E-P,-q r
p,q
The easy details are left to the reader). Remark.
Suppose that the hypotheses are as in Theorem 1.
Then
we also have the reverse rev(C**) of the double complex C**, such that the (p,q) 'th object in rev(C**) is Cq,p, and such that (rev C**) p,q d(O,l)
C** q,p 11(1,0)'
(rev C**) p,q d(l,O)
C** q,p
d (0, 1)·
The
450
Section 10
spectral sequence of the reverse of C** is called the second spectral sequence of the double complex C**. ('EP,q 'dP,q 'TP,q) r ' r ' r p,q,rE'l'
We will denote it
Thus explicitly,
r>O 'EP,q 0
Cq,p,
'EP,q
Hq(C*'P)
'EP,q 2
q * HP ((H (C , i)) . E 'l') .
1
and ~
.
This second spectral sequence of the double complex C** is in general very different from the one of Theorem 1, which is called the first spectral sequence of the double complex C**. However, the sets of partial abutments and the integrated partial abutments of these two spectral sequences are closely related, but usually with very different filtrations.
For
example, the "best possible" filtered cochain complex C*"', equation (4), for the first spectral sequence (such that the cohomology of C*A is the integrated partial abutments, equation (5), of the first spectral sequence) is the "worst possible" filtered cochain complex for the second spectral sequence -but with a very different filtration. versa.
And, of course, vice
The "traditional" filtered cochain complex C*, equation
(1), for the first spectral sequence is the
~
as the "trad-
itional" filtered cochain complex for the second spectral sequence -- but again with an in general very different filtration.
And similarly for the "dual of the traditional"
filtered cochain complexes D*"', equation (7.1).
Also, if the
Some Examples
451
functor "denumerable direct limit" is exact, then the direct limit abutments of both spectral sequences are both isomorphic as objects to what is traditionally called the "total cohomology" Hn(C**) = Hn(C*), equations (1) and (6'), of C**, but in general have entirely different filtrations.
Explicitly,
the p'th filtered piece of the filtration induced by the first spectral sequence is the image of H*(
1&
p' f-q , =n
cp',q')
n E 6'
+H*(
Sl
p' .fq , =n
cp',q')
n E 6'
p'~
and the p'th filtered piece of the filtration induced by the second spectral sequence is the image of H*(
1&
p' f-q , =n
cp',q')
n E 6'
q'~
which are in general very different. The most important abutment-like invariants, the integrated partial abutments, are in general not isomorphic for the two spectral sequences, not even as objects (forgetting filtration). However, in the very special case of Example 1.1.1 above, they do coincide as objects (but not in general as filtered objects); and then as observed in Example 1.1.1, these then also coincide (as objects) with the direct limit abutments of the exact couple of C*, and with the inverse limit abutments of the dual exact couple of D*
1\
(both of which are then simply the cohomology
of these cochain complexes ignoring filtration). Example 2.
The Spectral Sequence of a Composite Functor.
Theorem 2.
Let A, Band C be abelian categories, such that the
Section 10
452
categories A and B have enough injectives, and let F: A'VV>B n
be additive functors.
and G: B "SV>C
Let F , n
and (Go F) , n > 0, denote the riqht derived GoF respectively. (1)
n
0, G , n
>
0,
functors of F, G and
Suppose that
Q injective in Gn(F(Q))
~
=
A implies that
0 in C, for all integers n > 1.
Then, for every object A in
A, there is induced a conventional,
bigraded spectral sequence with abutment starting with the integer two such that "p,q "'2
( 2)
and such that the n'th object of the abutment is n H = (GoF)n(A), all integers n.
(3) Notes.
1.
Equation (2) implies that the spectral sequence is
first quadrant -- i.e., that E~,q
=
0 unless p,q > 0, all
integers r .:. 2. 2.
n The filtration on H is finite, for all integers n.
The proof of Theorem 2 is very well known, and need not be repeated.
The earliest published reference that I know is
[C.E.H.A.], near the end of the book. Remarks.
1.
The spectral sequence of Theorem 2 is the spectral
sequence of a double complex that vanishes outside the first quadrant.
(That is a special case of Example 1.1.1 above.)
The second spectral sequence of that double complex is also used in the proof of Theorem 2, to compute the abutment. 2.
If all the other hypotheses of Theorem 2 except possibly
Some Examples
453
condition (1) hold, then the conclusions of Theorem 2 hold iff condition (1) of Theorem 2 holds.
3.
Condition (1) (1')
is equivalent to:
A any object in A and n an integer that there exists an object A' in
~l
implies
A and
a mono-
morphism f: A ~ A' such that Gn(F(f»:Gn(F(A»~ Gn(F(A'» Exercise 1.
Let F: A '\N>B
categories, such that tives.
is the zero map in C.
A does
be an additive functor of abelian not necessarily have enough injec-
Then let us define a system of derived functors of F to
be (1)
A non-negative cohomological exact connected sequence of functors from A into B, together with
~ F O, such that
(2)
A map of functors n:F
(3)
For every obj ect A in A and every integer n
~
1, there
exists an object A' in A and a monomorphism f:A
~
A'
such that Fn(f) :Fn(A) ~ Fn(A') is the zero map in B, and (4)
For every object A in A, there exists a directed set D, and an exact sequence
of direct systems indexed by the directed set D in the abelian category A, where A denotes the "constant direct system A", such that the direct system indexed by D in the abelian category A,
454
Section 10
trivializes in the sense of section 6, Exercise 1 following Lemrna 7, and such that, the mapping of direct systems: (n
f l.
°
° ° °
1 1 )·ED:(Ker(F(Q.) .... F(Q·)))·Eo-,.(Ker(F (Q.) .... F (Q')))'Eo l l l l l l l
induces an isomorphism on the direct limit.
(Notice that by
section 6, Exercise 1, the direct limit of the leftmost direct system exists in rightmost
°
A; and, by left-exactness of F , the
direct system is isomorphic to the constant direct
system FO(A), and therefore has direct limit FO(A). Exercise 2.
It is not difficult to show that, if F: A'vu> B
is
a left-exact functor of abelian categories, then if a system of derived functors of F exists as in Exercise 1 above, then they are unique up to canonical isomorphism.
(Also, if the category
A has enough injectives, then the derived functors of F as in Exercise 1 above exist, and are canonically isomorphic to the usual derived functors as defined for example in [C.E.H.A.]). One can give examples of additive functors such that the derived tunctors as defined in Exercise 1 above do not exist. (For example, the functor F(A) = Hom(
n~l
(7./116':) ,A),
from the
category of finitely generated abelian groups into the category of abelian groups.) Exercise 3. F:
It can be shown that, given an additive functor
A~> B of abelian categories, if there exists a left-exact
functor FO: A ~> B
and a map of functors n:F .... FO such that
condition (3) of Exercise 1 holds, then FO is a universal leftexact functor into which F maps. false. )
(The converse is in general
Some Examples Exercise 4.
455
Theorem 2 can be generalized to a version that does
not involve injectives. Theorem 2'. and
G:B~~>C
Let A, Band C be abelian categories, let
F:A~~>B
be additive functors, such that the derived functors:
F* and G* of F and G exist.
Suppose also that condition (1')
of Remark 3 following Theorem 2 holds.
Then the derived functors
(GoF)* of GoF exist, and for every object A in A, we have a conventional bigraded spectral sequence starting with the integer two, such that
and such that the abutment is Hn
=
(GoF)n, all integers n.
And
Notes 1 and 2 following Theorem 2 above hold. Remarks.
1.
It is easy to show that, if all of the hypotheses
of Theorem 2' except possibly condition (1') hold, and if the conclusion of Theorem 2' holds, then condition (I') must hold. 2.
The proof of Exercise 2 is not difficult.
and 4 are far less obvious as stated.
Exercises 3
However, they can be
proved by an elegant method, using an (as yet unpublished) construction of the author, which he calls the category of direct limits . Example 3. The Adams Spectral Sequence We describe this construction only in very general terms, concerning only the spectral-sequence-theoretic aspects.
The
deep algebraic-topological aspects are handled well in the original reference [F.A.]. I am indebted to Professor John Harper of the University of Rochester for familiarizing me with this material.
456
Section 10
Definition 1.
A continuous function f: (X,x o )
+
(Y'Yo) of base-
pointed topological spaces is a stable homotopy fibration iff for every integer n, there exists a positive integer i
>
3
such that the induced mapping on the relative homotopy groups, i i i -1 '!Tn (S f): '!Tn (S X,S (f (Yo)))
i '!Tn (S Y)
+
(Where SZ is the suspension of Z, for all
is an isomorphism.
base-pointed topological spaces Z.
We define the suspension
of Z to be the double cone on Z, modulo the equivalence relation that identifies the double cone of the base-point to a point. ) Definition 2.
A spectrum Z is a sequence
(Zn'Tn)nE~'
indexed
by the integers, where Zn is a base-pointed topological space and Tn:SZn
+
Zn+l is a continuous, base-point preserving func-
tion, for all integers n.
If Z
=
(Zn,T ) and Y n
are spectra, then a map of spectra f: Z f = (fn) nE
~'
where f n : Zn
+
+
=
(Yn,on)
Y is a sequence
Yn is a continuous, base-point
preserving function such that the diagram of topological spaces and continuous functions:
.,
zn+l
'n
r
SZ
Yn + l
r
') SY
n Sf
°n
n
n
is commutative, for all integers n.
I f f:Z + Y is a map of
spectra, and i f Yn is the base-point of Y for all integers n, n'
Some Examples
457
- 1 (y))) E'7I (f -1 (y),T 1 S(f n n n n n n v. spectrum, which we call the fiber of the map f.
then th e sequence of fibers:
is a
If X is a base-pointed topological space, then define
X n
>
0,
<
O.
Then, since the functors Sand n are (X ) n E'Z' n
adjoint, the sequence
is in a natural way a spectrum, the associated
spectrum of X. Definition 3. the fiber.
Let f:Z
Y be a map of spectra and let F be
+
We say that f is a stable homotopy fibration iff
there exists an integer nO such that, whenever n continuous function: Zn
+
~
nO' the
Y is a stable homotopy fibration n
of base-pointed topological spaces in the sense of Definition 1. Then if f:X
+
Y is a continuous, base-point preserving function
of base-pointed topological spaces, and if (f ): (X ) n n
+
(Y ) is n
the induced map on the associated spectra, we have that f is a stable homotopy fibration in the sense of Definition 1 iff (fn) is a stable homotopy fibration in the sense of Definition 3. If Z and X are spectra, then for every integer n, define {Z,X}n = lim {homotopy classes of continuous, basek++oo
point preserving functions from Zn+k into XnH.} . Then {Z,X}n is an additive abelian group, for all integers n. If A is a pointed topological space with associated spectrum (A ) , and X is any spectrum, then define likewise k
458
Section 10
If B is any pointed topological space, then define likewise
for any spectrum or pointed topological space A, all integers
n. Also, for every spectrum Z, define
TI~lZ)
=
{SO,Zln' all integers n, TIslZ) is called the n'th
where sO is the zero sphere.
n
stable homotopy group of Z, for all integers n. Remark:
One traditionally assumes more hypotheses in the defin-
ition of a spectrum Z
=
(Z ,T) n
n n
E
7'
than we have in Definition
2 above, e.g., connectedness conditions on the maps Tn' n E 7'. For a spectrum Z obeying suitable such sets of conditions, one can show that, for any finite polyhedron A, that {A,Zln n < 0.
=
° for
(For example, this is so if Z is the spectrum of a
topological space.)
In particular, taking A to be the zero
sphere, it follows that TIst(Z) n
=
0 for n <
° and
for such a
spectrum Z. Lemma.
Let p:Z
~
X be a map of spectra that is a stable homo-
topy fibration, and let F be the fiber.
Then for every finite
polyhedron A there is induced a long exact sequence of abelian groups:
Proof:
The proof immediately reduces to the case in which Z
and X are spectra of topological spaces; and then replacing Z and X by the geometric realizations of their sing. cxs. and
Some Examples
459
replacing Z with an appropriate homotopy equivalent CW-complex Z' and the mapping Z'
~
X with an appropriate homotopic mapping,
we can assume that the continuous function homotopy lifting property.
f: Z
~
has the
But then the corresponding theorem
even for ordinary homotopy classes of maps: and A
-+ X
A
~
F, A
~
Z
X (rather than stable homotopy classes of maps) is
well-known, and implies the Lemma. Now, suppose that we have a sequence Xp' p E together with maps tp+l:Xp+l
~
~
, of spectra,
Xp that are stable homotopy
fibrations. p.
Let Yp + l be the fibers of these maps, all integers Then, by the above Lemma, for every finite polyhedron A,
we have a long exact sequence (1 )
()
Jl
{A,Y} p n- l~'"
where k is the inclusion from Y into X. Therefore, if we define ( 1.1)
vp,q
(1. 2)
EP,q
and
then V bigraded abelian groups, and we have the conventional, bigraded exact couple starting with the integer +1, (2)
Section 10
460
where k is of bidegree (0,0) and is induced by the inclusion k:Y
~
X, t is of bidegree (-1,+1) and is induced by the projec-
tions t:X
p+l
~ X
p'
so that h has bidegree (1,0). tral
a-p-q
and hP,q =
in the exact sequence (1),
By sec. 5 and 7, we have the spec-
sequence of the exact couple (2), which one can call a
generalized Adams spectral seguence.
It is a conventional, bi-
graded cohomological spectral sequence starting with the integer +1, such that
(3)
=
EP,q
1
{A,Y } P -p-q
The inverse limit abutments are
(4)
and the direct limit abutments are (5)
'H
n
=
lim {A,X
pt+a>
} +1 -p-n
As always, the inverse limit abutments are complete and the direct limit abutments are co-complete for their natural filtrations. As stated above, this construction is of course much too general to prove very much.
In the
"true" Adams spectral
sequence [F.A.j, for example, one assumes enough conditions on the spectra Y such that the groups {A,Y} are zero if n is p p n negative.
Then the spectral sequence (3) is zero outside of
the slanty half plane
n < O.
In addition, in the original
spectral sequence we have that Xp
=
therefore also Yp = (a point) for
p~
(a point) for p -1, whence
~
-1, and
Some Examples
o
for p
<
461
-1 ,
so that the spectral sequence is confined to the region: n
<
p~O,
0, i.e., to the shaded area below.
Figure 1 Also, we then have, by equation (1.1), that vp,q = 0 unless p
~
O.
Then from equation (5) it follows that the direct
limit abutments are all zero.
And, by section 7, Proposition
4, we have that the inverse limit abutments "H
n
are complete
and co-discrete. Therefore the inverse limit abutments will be an "honest" abutment iff the left defect is zero.
The (p,n-p)'th group of
the left defect is zero iff every element of {A,X}
p -n
---
that
comes from an element of {A,Xp+k}_n for all integers k > 0, comes from an element of the inverse limit. By section 9, Corollary 4.1, this will be so if the spectral sequence is such that the cycles stabilize.
However, this is
not trivially clear from the region pictured in Figure 1. However, for the special situation studied in the "true" Adams spectral sequence, one has a direct algebraic-topological proof that the cycles stabilize (see [F.A.]).
Therefore, by section
9, Corollary 4.1, it follows that the left defect is zero, and therefore: n The inverse limit abutments "H , n E., , are complete and
462
Section 10 co-discrete, and are an abutment in the sense of section 7, Definition 1.
Remarks:
1.
In the actual Adams spectral sequence, each Y p
is of the homotopy type of a finite direct product of K(n,n) 's. Therefore, for each p, {A,Y} is zero for all but finitely p n many n.
In terms of the spectral sequence, this means that in
Figure 1 for EP,q , each vertical line has only finitely many 1
non-zero terms.
(However, that in itself is not enough to
imply that the cycles stabilize.) 2.
Also, in the actual Adams' spectral sequence, Adams
proves that, for every integer n, there exists an integer rO ro(n), such that for all integers p the cycles in degree (p,n-p) stabilize past the integer rO
=
rO(n).
By section 9, Proposi-
tion 1, it is equivalent to say that r
[(t °V)n(Ker t))p,n-p=[(t-divisible part of V)n(Ker t))p,n-~ for all integers p.
But then, by Lemma 2.1 and the Remark
following, we have that
[(troV)n(t-torsion part of V))p,n-p=[(t-divisible part of V)n (t-torsion part of V))p,n-p i but since vp,n-p
=
0 if P < 0,
(t-torsion part of V)
V.
Therefore (t-divisible part of V)p,n- p , for all integers p. Of course, the above condition implies that the cycles
Some Examples
463
stabilize, and therefore (section 9, Corollary 4.1) that the left defect is zero.
Therefore
(t-divisible part of V)n(t-torsion part of V)
=
(infinitely
t-divisible part of V)n(t-torsion part of V), i.e., every t-divisible element in vp,q is infinitely t-divisible, for all p,q Therefore, we have that
(infinitely t-divisible part of V)p,n-p ,
for all integers p.
That is:
exists an integer rO
=
u
E {A,X}
p n
For every fixed integer TI, there
rO(-n), such that if p
o=
for all integers i
>
0
u and such that {A,projectioni+l}n maps u i + l
into u ' for all integers i i 3.
0 and if
is the image of an element in {A,X + } , then p rO n
there exist elements u1.' E {A,X +' } P 1. n such that U
~
>
0
Spectral sequence-theoretically, to obtain the results
indicated in Remark 2, all that is needed (see sec. 9, Rk. 1 after Prop. 5) is: That the cycles stabilize, and that the spectral sequence is semi-stable (sec. 9, Rk.3 after Prop.5.1). a lower (or upper) half plane spec. seq. is automatically 4.
(And
sem~s~le).
Since the spectral sequence is confined to the lower
half plane, we have trivially that the boundaries stabilize. Therefore the fact that the cycles stabilize implies that the spectral sequence converges. 5.
In a later construction I understand that Adams
produced an alternate construction of an "Adams' spectral
464
Section 10
sequence," that also comes from an exact couple, but in this case one such that vp,q
=
0 whenever p > O.
Therefore the
spectral sequence in that case is confined to the left half plane, and the inverse limit abutments vanish. 7, Proposition 4, part (2), we have that:
And by section
The direct limit
abutments 'Hn, n E 7 , are discrete and co-complete, and are an abutment for the spectral sequence.
(Notice that for such
a spectral sequence, we do not need to know that the stable homotopy { }n vanishes in negative dimensions.)
CHAPTER 1 THE GENERALIZED BOCKSTEIN SPECTRAL SEQUENCE
Let
A
be a ring with identity and let
element in the center of the ring A. Let
A1\t
pletion of
Then
A
for the t-adic topology. n
n
c* = (C , d ) nE.?!'
Let
tE
A
be a fixed
denote the comAl'lt
is a ring.
be a cochain complex of left A-modules
indexed by all the integers, such that multiplication by t:C
n
~ c
n
is injective (i.e., such that
t-torsion), all integers
o
n.
n C
has no non-zero
Then from the short exact sequence:
~ C* ~ C* ~ C*/tC* ~ 0
of cochain complexes of left A-modules, we obtain the long exact sequence of cohomology: (1) If we let
V =(Hn(C*»
nEZ'
and
E = (H
n
(C* /tC*) ) nE.?!' then the long
exact sequence (1) can be "wrapped around" to give the singly graded exact couple (see Introduction Chapter 2, section 5) (2)
where ~
t
is degree-preserving and is multiplication by
is degree-preserving and induced by the natural maps: 465
tEA,
Chapter 1
466
n Hn (C*) .... H (C* /tC*) n E 'l' , and
d
increases degrees by one and
is induced by the coboundaries in the long exact sequence (1). Therefore this exact couple is a conventional, singly graded exact couple as defined in Introduction, Chapter 2, section 5. Then, see the Introduction, Chapter
2, section 5, Definitio
5', we have the associated spectral sequence of the exact couple (2), which is a conventional, singly graded spectral sequence starting with the integer zero, where n En = H (C* /tC*) , all integers
( 3)
n E'Z ,
o
(i.e.
EO
=
the graded group E).
This spectral sequence is
called the Bockstein spectral sequence of the cochain complex C*
with respect to the element
t
in the center of
A.
As usual, the r'th derived couple of the exact couple (2) is an exact couple, of the form: (4) d
where
trV
is the graded subgroup of
subquotient of
o
r
V, Enr
E~, and the other two maps
and +1) are determined from
1T
at
-r
and
is of course a 1T
d,
r
,
d
r
respectively,
the exact couple (2) by passing to the subquotient. is the cohomology of the cochain complex boundary the n'th coordinate of
1T
r
En r
(of degree in
And
,with n'th co-
nd • r
Studying the exact couples (2) and (4), we have seen in the Introduction, Chapter 2, section 5, Corollary 3.1' equations (lr) and (2 r ), and Corollary 3.2', equations
(lrl and (2 ), that r
Bockstein Spectral Sequence Lemma 1. (1)
Let
n
be an integer.
Then
uE En = Hn(C*/tc*)
An element
is an r-fold cycle
o
dn:Hn(C*/tc*) ~ Hn+l(C*)
iff its image under the coboundary of (2)
The restriction of
d
467
n
Hn+l(C*),
induces an epimorphism:
(One might call this latter group: "precise t-torsion in Hn+l(C*) (3) subgroup in
that is r-times t-divisible"), The r-fold boundaries in n Ker (t r :H (C*)
-+
are the image of the r (this is the "precise t -torsion
Hn (C*))
Hn(C*)") under the natural map:
and (4)
n u E H (C*)
An element
is such that the image under
the natural map: boundary iff there exist v
v,wE Hn(C*)
with v E Kert
a precise tr-torsion element) such that
Definition.
uE M,
we say that
t-torsion element iff t·u = 0; if tr-torsion element iff
tr·u
iff there exists an integer tr-torsion element.
n
tr·M.
=
(Le.,
v + two
Let us introduce some terminology formally.
M is a left A-module and
u E
u
r
u
r u
0;
r
~
We say that
~
0
then
u
is a 12 reci se u is a 12 reci se
is a t-torsion element such that
0
u
If
u
is a precise
is t-divisible iff
is infinitely t-divisible iff there exists a
r~O
sequence of elements u
= u o'
ur,r
~
0, of elements of
M, such that
all integers r ~ O. t·u + l = u ' r r Then, by Introduction, Chapter 2, section 5, Corollaries and such that
3.1' and 3.2', equations (1) and (2) of both Corollaries, we
468
Chapter 1
have that Corollary 1.1. (1)
Under the hypotheses of Lemma 1
An element
E E~
u
= Hn(C*/tc*)
iff its image under the coboundary
is a permanent cycle
dn:Hn(C*/tc*)
+
Hn+l(C*)
is
t-divisible. (2)
The restriction of the n'th coboundary in the long
exact sequence (1) induces an epimorphism of left A-modules (in fact of left (A/tA)-modules) ZOO(E~)
it-divisible, precise t-torsion elements in
+
Hn+l(C*) } The permanent boundaries in
(3)
the natural map: it-torsion in
Hn(C*)
E~
Hn(C*/tc*)
of the subgroup
Hn(C*)}.
An element
(4)
+
are the image under
the natural map:
u E Hn(C*)
n H (c*)
boundary iff there exist
+
is such that the image under
n H (c*/tC*)
E~
v,w E Hn(C*)
is a permanent
with
vat-torsion
u = v + two
element such that
Then, by Introduction, Chapter 2, section 5, Theorem 4', we have Theorem 2.
Let
A
be a ring with identity, let
element in the center of the ring complex of A-modules.
A, and let
denotes the
be an
be any cochain
Then consider the singly graded, cohomo-
logical spectral sequence defined above.
If
~
t
It starts with
Eoo-term, then for each integer
the short exact sequence of A/tA-modules:
n
we have
Bockstein Spectral Sequence (1)
o
+
469
(A/tA) 8~n(C*)/(t-torsionD A
t-divisible, precise t-torsiOn) ( elements in Hn + l (C*)
+
O.
The monomorphism in the short exact sequence (1) by the natural map:
Hn(C*)
+
Hn(C*/tc*), while the epimorphism
in the short exact sequence (1) dn:Hn(C*/tc*)
+
is induced
is induced by the n'th coboundary
Hn+l(C*), in the long exact sequence of cohomol-
ogy. Remarks 1.
I was first made aware of the Bockstein spectral
sequence by Birger Iversen, in the case that in fact a discrete valuation ring, and erated A-module, all
n E 7
cn
A
is Noetherian,
is a finitely gen-
(Then the third group in the
short exact sequence of Theorem 2 vanishes, so that the monomorphism in that sequence is an isomorphism).
However, we need
the greater generality. 2.
Much of the preceding depends
only on the long exact
sequence of cohomology (1) at the beginning of the chapter. More precisely,
(and more generally), let:
dn - l n ->V be any long exact sequence of abelian groups and homomorphisms, indexed by all the integers,
(such that the groups in spots
congruent to zero mod 3 are equal to those in spots congruent to one mod 3, as indicated in the display of the sequence). Then we can define a singly graded exact couple by defining
n
V = (V ) nEzr '
Chapter 1
470
where
t
is deduced from the
is deduced from the deduced from the
d
TIn n
tn
and is of degree zero,
and is of degree zero and
and is of degree plus one.
a singly graded cohomological spectral sequence
d
IT
is
Then we obtain E~,
r ~ 0,
such that
and all the results of Lemma 1, Corollary 1.1 and Theorem 2 hold (with
"~,,
replacing
"Hn(C*/tC*}" throughout.} A-module where
A
the endomorphism
=
"Hn(C*)" (Here,
and
~
n "H "
replacing
can be regarded as an
P[Tj, and where the action of
tn
of the abelian group
T
on
n V
is
~, all integers
Taking this point of view allows us to use terminology
n EP
such as lit-torsion", "t-divisible", etc., in Definition 1 above). (A practical application of Remark 2 is that, if one is working with a cohomology theory, such as e.g. cohomology of sheaves, one might work directly with a long exact sequence of cohomology, without worrying whether it comes from cochains) . Remark 3.
Do results generalize to other abelian categories?
Of course the answer is "yes." Assume, for simplicity, that
Let
A be any abelian category.
A has the property that denumenble
infima and suprema of subobjects exist.
(E.g., this is the case
if denumerable direct sums and denumerable direct products of objects exist).
Then we pose a definition.
object, and
+
t:A
A
If
A
is any
is any map, then the precise t-torsion
471
Bockstein Spectral Sequence in
A
is Ker(t); the precise {-torsion in
integers r
~
O.
A
is Ker(t r ), all
Also we define the t-torsion in
supremum of the subobjects of
L
A:
A
to be the
(precise {-torsion in
A) .
r>O We also define the infinite t-torsion in Ker(A
+
lim (A
t
+
A
t
+
A
t
+
A
t
+
... )) ,
A
to be
whenever the direct limit
+
exists.
Notice that the infinite t-torsion contains the t-
torsion - sometimes properly, if denumerable direct limit is not an exact functor.
We define the t-divisible part of
be the infimum of the subobjects:
n (Im(tr:A
+
A)).
A
to
The
r~O
infinitely t-divisible part of [lim( ... ~ A ~ A ~ A)l exists.
+
A
is the image of the map:
A, whenever the indicated inverse limit
Notice that the infinitely t-divisible part of
A
is
contained in the t-divisible part, sometimes properly, when denumerable inverse limits are not exact.
(Note:
As we have
observed in Introduction, Chapter 2, section 2, Example 2, the concepts of "t-torsion part" and "t-divisible part" are selfdual, in the sense that one flips into the other (modulo the usual one-to-one correspondence between subobjects and quotient objects of a fixed object
A
passing to the dual category).
in a fixed abelian category after Similarly for "infinite t-torsion
part" and "infinitely t-divisible part".)
Then, the generaliza-
tion of Ie. g., Theorem 2 to abelian categories
(which
follows from Introduction, Chapter 2, section 5. Theorem 4') is: Theorem 2'.
Let
A be an abelian category such that denumer-
able suprema and infima of subobjects exist.(*)
Let
(*) If one deletes this hypothesis, there would be some difficulty in defining "permanent cycles", "permanent boundaries" or "E~" ,.•hen attempting to construct the indicated spectral sequence.
472
Chapter 1
be any long exact sequence, indexed by all the integers, in the abelian category
A (such that the objects in any spot con-
gruent to zero mod 3 is the same as that in the next spot, congruent toone mod 3, as indicated in the display).
Then there is
induced a singly graded, cohomological spectral sequence, such that
E~
n H , all integers
and such that, for each integer
n,
n,
we have a short exact
sequence: (2)
o ~ [Vn/(t n -torsion part of Vn »)/ t n . [vP/(t n -torsion part of Vn ») ~ En ~ (t-divisible, precise t-torsion 00 part of ~+l) ~ 0,
where the monomorphism, respectively epimorphism, in this sequence is induced by
nn' respectively
n d ,
where
lit • [~/(t -torsion part of V»)" denotes the image of the n
n
n
endomorphism induced by
of the object:
part of V »), and where
is the n'th group of the
n
Eoo-term
of the indicated spectral sequence. Theorem 2' is of course a special case of Introduction, Chapter 2, section 5, Theorem 4'.
And of course, Lemma 1, and
Corollary 1.1 also generalize to the hypotheses of Theorem Remark.
2~
As we have observed in Introduction, Chap. 2, section 5,
Remark 2' after Theorem 4', notice that the short exact sequence (2) of Theorem 2' is self-dual--that is, if we pass to the dual
Bockstein Spectral Sequence abelian category
O
A
,
473
and re-index the sequence (1)
so as to
obtain an analogous long exact sequence in the category
AO ,
and therefore also a Bockstein spectral sequence (cohomological, singly graded)
in
O
A , and a short exact sequence
(2°)
in
AO
analogous to (2), then the sequence (2°) is simply the sequence (2) thrown into the dual category (and "written backwards") , with the first and third terms interchanged.
Thus, at this
level, the "t-divisible" third term in the sequence (2) becomes symmetrical to the more "ordinary looking" first term in that sequence. Also, the short exact sequence of Theorem 2' has an analogue for
instead of
Namely, if
abelian category,
(whether or not
A has the property that
A
is any
denumerable sups and infs of subobjects exist), if
C*
cochain complex (indexed by all the integers) and if is any endomorphism of all integers
C*
such that
t
n, then for every integer
is a t*:C*
~
C*
is a monomorphism,
n
r
~
we have the
0
short exact sequence (2' ) r
o
~ (A/tA)0{precise tr-torsion part of Hn(C*)) ~ En A r
t·(precise tr+l-torsion part of Hn+l(C*)) ~ (Here we have used notations as if where element
A
is a ring, t*:C*
+
C*
tEA in the center of
-+
o.
A = category of left A-modules,
is multiplication by some A.
In the general case, if
is any object in an abelian category and
t:M
~
M a map, then
"(A/tA) 0M" must of course be replaced by "Coker(t:M ~ M) ". A (Of course, Also tlt·M" is understood to be "Im(t:M -+ M) "). also, all exact sequences in this Chapter involving
En r
(as
M
474
Chapter 1 En) hold for any abelian category, even if denumer00
opposed to
able suprema and/or infima of subobjects do not exist).
The
proof is Introduction, Chapter 2, section 5, Corollary 2.2' Remark 4.
One might wonder, can one generalize Theorem 2'
(and
Lemma 1, Corollary 1.1, and the exact sequences in the preceding Remark,) to cochain complexes not injective?
C*
such that
t*:C*
~
C*
is
The answer is "yes", even at the abelian category
level.
A be an abelian category (such that infima and suprema
Let
of denumerable sets of subobjects of objects exist), let be a cochain complex in let
t*:C*
~
C*
C*
A ( indexed by all the integers) and
be any map of cochain complexes (not necessarily
a monomorphism).
Then we define the (generalized) Bockstein n
n
r
r
spectral seguence, a simply graded spectral sequence, (E ,d ) ElI n
.
r.::O Namely, for each integer a coboundary [LA. C.]) that
n
define
dn:O n ~ on+l n
n D
=
Cn x e n + l , and define
by requiring (in terms of elements n
n n+l d (u, v) = (d (u) +t (v), -d (v)) , Then
0*
=
n n (0 ,d )nE;?!,
11 -indexed cochain complex in the abelian category
e*(+l )
be the cochain complex such that
n'th coboundary is
n _d + l ,
first injection, and d*:O* (Thus,
n E ~. ~
Let
is a A.
Let
1 e n (+ 1) -_ en + , and the 'IT*: C* .. D*
denote the
C*(+l) the second projection.
')[n(u) = (u,O) ,dn(u,v) = v, all
u EC n , vE
c n + l , nE
11 ).
Then we have a short exact sequence of (1/ -indexed) cochain complexes in the abelian category
A:
(0) 0 ~ C* ~*O* §* C*(+l) ~ O.
Noting that
Hn(C*(+l)) =
n+l H (C*), the long exact cohomology sequence of the short exact
Bockstein Spectral Sequence
475
sequence (0) is of the form: T
(1)
where
and
T
n+l
n+l
is the n'th coboundary
of the cohomology sequence of the short exact sequence (0), all is an endomorphism of n H (C*), all
n E 7.
An explicit computation,
uSing the
usual construction of the coboundary, shows that where
t*:C*
~
C*
the cochain complex
n Tn = H (t*) ,
is the orginally specified endomorphism of C*.
But then the long exact sequence (1)
is such that Lemma 1, Corollary 1.1, Theorem 2 (or more precisely, Theorem 2') and all the exact sequences of the last Remark hold (with "Hn(D*)"
replacing
"Hn(C*/tC*) ",
n E
;1).
There-
fore, we have the generalized Bockstein spectral seguence with
obeying Theorem 2'
and
(and Lemma 1, Corollary 1.1,
and the last Remark all hold). Theorem 2'.
This generalizes
(Because in the special case that the hypotheses
of Theorem 2' hold (i.e., is easy to see that the
t*:C*
~
C*
is a monomorphism)
Hn(D*) ~ Hn(C*/tC*)
it
canonically, and
similarly for the Bockstein spectral sequence of Theorem 2' and the one just constructed. below) .
(*)
For a proof of this, see the footnote
(*)
The construction of this last Remark can be motivated as
fOllows.
Consider the special case in which
of A-modules, where
A is the category
A is a commutative ring, and
tE A
is an
element that is not a divisor of zero, and such that the given
Chapter 1
476
endomorphism
t*:C*
~
C*
(which we are not assuming to be
injective) of the given cochain complex by
t".
There exists a
-indexed cochain complex
7
of A-modules and map of cochain complexes of A-modules ~
a*:C*
C*
such that (1)
induces an isomorphism on cohon n Multiplication by t:'C ~ 'C is injective,
mology, and (2) all integers acyclic
n E
'?
[C.E.H.A., pg. 363] choose an
~uch
n E 'l' ,
then
'
P~ ~ p~+l
~**
that if we define
Then
Bockstein spectral seguence of ~
'C*.
(2)
resolution of
-m
Let
AltA
p*
t:C*
~
as right A-module. F*.
'C
all
Define 'C* =
n
is projective,
n
a*:'C*
,
~ 'C +
C*
n
is inthat in-
Then define the generalized
be any flat
obtaining a cochain complex
'C
t":
n E 'l' ; and we have a map
duces an isomorphism on cohomology). t:'c*
c-n,m=pn
is a double cochain complex.
n E 'l' , so that "multiplication by
jective, all
c n ~ c n+l ,
over the coboundary:
the associated singly graded complex. all
P~,
proiective homological resolution of en, call i t
all integers
E
a*
(E.g.,
,?
and choose a map:
n,m
is "multiplication
Then we give three alternative constructions of the
spectral sequence.
'C*
C*
C*
to be that of
(e.g., projective) Define Fn = P-n' "Hn(F*® C*)"
Then if one uses
A
"Hn(c*/tc*)"
in lieu of
of Theorem 2 one obtains a long exact
sequence (see "percohomology", chapter 5 below, for details), n-l dn +l _d__ >H n (C*)---1>H n (C*)->H n (F* ® C*) - - > A
which gives rise to a Bockstein spectral sequence.
'C*
and
F*
as in (1) and (2).
Then use
(3)
Choose
"Hn(F* ® 'C*)"
in
A
lieu of
"Hn(c*/tC*) "
of Theorem 2, giving rise to a long exact
sequence: (1)
which yields a Bockstein spectral sequence.
(The long exact
Bockstein Spectral Sequence
477
sequences constructed in (3) map into that constructed in (1) (using the map of cochain complexes: (A/tA)
F* .... (A/tA) , where
is regarded as a cochain complex concentrated in dimen-
sion zero)
and the long exact sequence in (3) also maps into
I
that in (2)
a:' C* .... C*) .
(using the map
three constructions (1),
(2),
(3),
This shows that the
yield canonically isomorphic
long exact sequences, and therefore also generalized Bockstein spectral sequences - and also, that the long exact sequence, and also generalized Bockstein spectral sequence, constructed in (1) 'C*
is independent of the choice of such a cochain complex
and map
a*).
A special case of the construction (2) is as follows. specific projective resolution of the A-module
o .... A P
by
t).
0,
n
F- l
=
FO
=
A,
is
.... A/tA .... 0
n"l
0,1.
d
l
(multiplication
=
The corresponding cochain complex
o .... i.e. ,
1A
A/tA
A
F*
is
° . . A ....t A .... ° . . ° . . F
n
=
0,
n "I -1,0,
d- l
=
"multiplication
F* ® 'C* F;j D* , the cochain complex constructed A in the Remark above (which was constructed in any abelian
by
til.
category
But then
A).
Thus, the long exact sequence and the generalized
Bockstein spectral sequence constructed in that Remark, special case by
t,
tEA
A = category of A-modules,
t*
=
in the
multiplication
a non-zero divisor, coincides with the one con-
structed in this footnote. This shows that: 1.
In the construction in Remark 4 above,
T
n
H
n
(t*),
as previously asserted. (Proof:
By the Exact Imbedding Theorem
[IAC~,
to prove such an
Chapter 1
478
A = category of
assertion, it suffices to prove the case: abelian groups. acts on
en
Then regard
as a
7 [Tl-module,
where
T
Therefore we are reduced to
E ;[.
n
as
e*
proving the assertion under the hypotheses of this footnote, in the special case
A
=
7 [Tl,
observed in this footnote,
t
=
T.
But then, as we have
Hn(D*) = construction (2) of this
footnote, which we have demonstrated to have the desired properQ.E.D. )
ties. 2.
Under the hypotheses of Remark 4 above, in the special
case that
t*:C*
~
C*
is a monomorphism, then the long exact
sequence and generalized Bockstein spectral sequence constructed in Remark 4 above are canonically isomorphic to those in Theorem (Proof:
2'.
Again, using the Exact Imbedding Theorem [I.ACJ,
A = category
it suffices to prove the assertion in the case that of
7 [Tl-modules, and
where
t
=
TE 7 [Tl
=
t*:e* A.
->-
C*
is "multiplication by
t",
But then, the construction of the
above Remark is the special case construction (2) of this footnote when ~
0
=
P* ~
A
t
~
A
(the projective resolution: ->-
A/tA
->-
0)
of the A-module,
A/tA.
And the
construction of Theorem 2' in this case is the special case construction (1) of this footnote, with' 'e* = e*,
0.*
=
identity.
Therefore, the proof of observation 2 follows from the fact, observed above, that the three constructions (1),
(2),
(3) of
this footnote all yield canonically isomorphic long exact sequencE and generalized Bockstein spectral sequences.)
Remark 5.
It should be noted that every singly graded exact
couple (in any abelian category) :
479
Bockstein Spectral Sequence
V -->V
\1 E
~
that is such that the map:
V
such that the maps:
and
V
E
+
V
is of the degree zero, and E
+
V
are maps of singly
graded objects, of whatever (possibly different)
degrees,
can
be re-interpreted as a long exact sequence as in the hypotheses of Theorem 2' of Remark 3 above graded objects E
and
maps:
E
V
E
~
and
is positive and
+
V. V
n
to
-n
is not
-r,
to make it
E
If the sum of the degrees of the +1, then:
+r, then we obtain
sequences; negative and E
(possibly after reindexing the
r
e.g.,
such long exact
then we re-index
+r,
if this integer
n V
to
V-n ,
and proceed as in the last case.
(The case in which this integer is zero is trivial, and reduces to denumerably many ungraded exact couples, another special case)).
Therefore essentially every singly graded exact couple
in every abelian category,
such that the map
t:V
+
V
of the
exact couple is of degree zero, is covered by Theorem 2' of Remark 3. The observations of this last Remark are related to those made in Intro. Chap.2, section 4, Remark following Example 3. We conclude this section with a corollary to Theorem 2: Proposition 3.
Under the hypotheses of Theorem 2, suppose that
the ring
is left Noetherian.
A/tA
suppose that
Hn(C*/tc*)
Let
n
be an integer and
is finitely generated as a left A-
module (equivalently, as left (A/tA)-modula. an integer
(1)
r,
Then there exists
depending on the fixed integer n-l d r +l
..• =dn s
l
= 0,
all
n,
s ~ r
such that
480
Chapter 1
(2)
u E Hn(c*/tc*)
If
element in
Hn(C*), then
element in
Hn(C*)
then
dn-l(u) If
(4)
that
=
u
is the image of a precise tr-torsion
and
u E Hn(C*)
tr·v
n n d - l (u) E t r .H (C*),
is such that
is t-divisible in
Hn(C*).
is a precise t-torsion element such v E Hn(C*),
for some
Let
(5)
u
u E Hn - l (C*/tC*)
If
(3)
is the image of at-torsion
u E Hn(C*)
then
is t-divisible.
u
be any t-torsion element of
Hn(C*).
Then the following conditions are equivalent:
u
t-divisible;
v E Hn(C*)
that Note:
u
=
u
is t-divisible; there exists
is infinitely
tr·v.
Whether or not
A, AAt
of
AltA
is left Noetherian,
under the other hypotheses of Prop. 3, whether or not is finitely generated, for every pair of integers r~O,
such
conditions (1),
(2),
(3),
(4)
Hn(C*)
n,r
with
and (5), in the statement
of the Proposition are equivalent. Proof.
First, let us prove the Note.
In fact, by definition
of a spectral sequence, n-l d r +l
0,
But by Lemma 1, part (3), the image of a precise Corollary 1.1, part (3),
u E
E~
all integers
is in
image of a t-torsion element in
is in Hn(C*).
~
r
u
iff
tr-torsion element in u E E~
s
Boo(E~)
is
Hn(C*); and by iff
u
is the
This proves (1)<=> (2).
Bockstein Spectral Sequence
481 u ~ E~-l
On the other hand, by part (1) of Lemma 1, if u E Zr(E~-l)
iff
d
n-1
(u) E t
Corollary 1. 1, i f
u E E~-l
is t-divisible in
Hn(C*).
Next,
(3)
<=>
of Corollary 1.1. element, and
·H (C*); and by part (1) of u E Z'" (E~-l)
This proves (1)
d n - l (u)
iff
<=>
(3).
(4) by using part (2) of Lemma 1 and part (2) {u E Hn(C*):
such that
=
u
u
is a precise t-torsion
try in Hn(C*)}
=
{d n (w):w E Zr (EOn-l ) } , by part (2) of Lemma 1; and u
then
n
then
(Since
3v
r
n {u E H (C*) :
is a precise t-torsion, t-divisible element} =
{d n (w):w E Z'" (EOn-l )}, by part (2) of Corollary 1.1). Finally, obviously
(5)
remains to show that (4)
=>
=>
element such that there exists u
To prove the Note, it
(5). That is, we must show that,
under the hypotheses of (4), if
then
(4).
u E Hn(C*) v E Hn(C*)
is infinitely t-divisible.
is at-torsion such that
u = tr·v,
We first show that
u
is
t-divisib1e. Since
u
is a t-torsion element of
h ~ 0
an integer
such that
th.u
=
O.
Hn(C*), there exists The proof that
u
is
t-divisib1e now precedes by induction on the non-negative integer
h.
If
h
=
0, or resp. 1, then
assertion follows from condition (4). We have that (4),
th·u
u = tr·v
=
O.
Therefore
for some
u
=
0, or resp. the
So assume that
th-l. (tu)
=
O.
that
t·u
In fact, if
is t-divisible. N
We now show that
is any integer
divisible, there exists
By condition
v E Hn(C*), and therefore
Therefore, by the inductive assumption applied to
~
u
r+1, then since
w E Hn(C*)
such that
h > 1.
(tu) = tr. (tv). t·u,
we have
is t-divisible. t·u
is t-
Chapter 1
482 But then
u = tN-I·w+o:, t·o: = O.
where
We also have, since
t r . (tN-I-r) ·w,
t·o: = 0,
so that
and
t-divisible.
=
u-t
~
r+l, that
t
N-I
w = Thus,
w
is
0:
0:
In particular, we can write
S E Hn(C*).
exists
0:
N-I
N
0:
=
tN-I·S,
there
But u
t
N-l
w+a,
so that u
= ~
N
being an arbitrary positive integer
u
is t-divisible, proving the induction.
r+l,
it follows that
Thus, under the hypotheses of condition (4), we have shown that,
if
u
is any t-torsion element in u
In fact,
since
u u
is t-divisible.
is infinitely t-divisible. is t-divisible, we can write Then
Let Since u
l
=
u
is a t-torsion element, so is
2
=
u . l
But since
tr.ui' it follows from the last proved assertion that
is t-divisible. u
To
(4) => (5), we must show, under this
complete the proof that same hypothesis, that
Hn(C*), and if
t
r
·u
2,
etc.
u
l
Define
But then we can write
Proceeding by induction, we obtain a sequence (EXplicitly,
having defined us,s
~
1, and establised that
u
s
is at-torsion,
Bockstein Spectral Sequence t-divisible element, choose
483
such that
u~+l
u •
s tr·u' ) Thus, u is an infinitely u s +l = s+l . t-divisible element of Hn(C*), as asserted. This completes
Then define
the proof of Note 1.
It remains to prove the Proposition.
In fact, consider the (A/tA)-module hypothesis, this is Boo(E~)
Hn(C*/tc*)
is a submodule.
Since by hypothesis the ring
as a left (A/tA)-module.
Boo(E~)
But
Boo(E~)
is the increasing union
is finitely generated as
follows that there exists an integer Br(E~)
=
Boo(E~).
r n B (EO)' r
r
s
~
~
O.
(A/tAl-module, it ~
0
such that
But then, by the general theory of spectral
sequences, this is equivalent to integers
(A/tA)
is finitely generated
of the sequence of left (A/tA)-submodules:
Boo(E~)
E~. By
a finitely generated left (A/tA)-module.
is left Noetherian, likewise
Since
=
=
••• = d
n
s
=
0, all
1, and this is condition (1) of the Proposition.
Q.E.D. Corollary 3.1.
Let
A
t ~ A
be a ring with identity and let
be an element of the center of the ring
A.
Let
be a cochain complex of left A-modules indexed by all the m integers, such that multiplication by t:c m ~ c is injective, all integers
m.
Let
n
be any fixed integer and let
any fixed non-negative integer.
Let
M
=
r
be
{t-torsion inHn(c*)}.
Then the five equivalent conditions of Proposition 3 are all equivalent to each of the following conditions: (5' )
M
as left submodules of elements of
M} and
M, T
=
D+T
where
D = {infinitely t-divisible
{precise tr-torsion elements in
M}
484
Chapter 1
(5" )
D+T
M
as left submodules of
M,
where
D
is some left submodule of
M every element of which is t-divisible, and submodule of
M such that
tr'T
T
is a left
= {oJ.
There exists a short sequence of left A-modules
(5 "')
o
D
~
~
M
~
T
~
0,
where D is a left A-module every element of which is t-divisible, and
tr'T
= {oJ.
In which case, the sequence (5'") is uniquely determined up to canonical isomorphism preserving image of
D
M -- that is, the
is necessarily {x E M: x is t-divisible} and
is necessarily isomorphic to the quotient A-module. this is the case, if
x E T
x' E M such that
th·x'
Proof.
(5')
Obviously,
=
and
°
=>
in (5'") to coincide with
=
Also, when
0, then there exists
and the image of
(5").
D
th·x
T
x'
in
Also (5") => (5"')
T
is
(Take
x.
D
in (5"), and complete to a short
exact sequence). Also,
(5'") => condition (5) of Proposition 3:
suppose that (5 "') holds, and let element in
n H (C*)
v E Hn(C*l
such that
(i.e., u E M) u = tr·v.
In fact,
n u E H (C*) be at-torsion be such that there exists Then
v E M.
Throwing through
the epimorphism of the short exact sequence in (5"'), we see that the image of But
tr'T
Therefore
= {oJ. u E D.
u
in
T
is in the subgroup
Therefore the image of
u
in
tr'T T
of
T.
is zero.
Since every element of the left A-module
D
is t-divisible, every element of D is also infinitely t-divisible.
Bockstein Spectral Sequence Therefore
u
485
is infinitely t-divisible, proving condition (5).
To complete the proof of the equivalence of conditions (5), (5'),
(5"),
and (5"') i t suffices to show that (5) implies (5').
In fact, assume condition (5) and let v ~ tr·u
tion (5), M.
t-divisible element of
v ~ tr·w,
of
But then if
M.
cise tr-torsion elt. of u = w+x,
where
w
x
u-w,
tr. x ~ t
M (since
~
r
it follows that
M
M}
elements of
is an infinitely
• u_t
x r
is a pre-
• w~v-v=O), so
the sum of an infinitely t-divisible element
and a precise tr-torsion elt. of M.
M
Then by condi-
is an infinitely t-divisible element of
Therefore we can write
that
u E M.
=
D+T,
and
T
=
where
D
=
uEM
being arbitrary,
{infinitely t-divisible
{precise tr-torsion elements in M}.
This proves (5'), completing the proof of the equivalence of (5),
(5'),
(5"),
and (5"').
Assume now that we have a short exact sequence as in (5"'). To show that the image of
D
is necessarily
{x E M: x is t-
divisible}. We can assume that the monomorphism: inclusion. in
T
Let
x E M
be t-divisible.
of
is zero. D
Then the image of
Therefore
xED.
Therefore the image of
x
Therefore
D D
~
x
in
Conversely, since every element
is t-divisible considered as an element of
element of
of
is an
is t-divisible, and in particular lies in the submodule
{a}. T
D ~ M
D,
every
is t-divisible considered as an element of
M.
{x E M:x is t-divisible considered as an element
M}. Finally, to complete the proof of the Corollary, let x E T
and let T.
h
be a non-negative integer such that
We must find an
x' E M
representing
x
th·x = 0 such that
in
486
Chapter 1
o
in
M.
In fact,
let
the image of fore
th·u
u E M be any element representing
th·u
in
T
is zero.
exists an infinitely t-divisible element v E D)
element
=
th.x' u
=
0
(since
x'+v.
Since
T
is
th·x'
u
in
=
tho (u-v)
v E D,
But the image of in
th.v = th.u.
such that
u
and
T
is
x' x.
E M (i.e., an
Let
=
x'
th.u_th·v
=
u-v.
0),
Then
and
have the same image in Therefore the image of
T. x'
Q.E.D.
X.
Remarks: 1.
There-
Therefore there
M.
v
Then
th.u E D.
Therefore
is infinitely t-divisible in
x.
If the ring
A
should be a principle ideal domain,
then the short exact sequence of A-modules (5"') of Corollary 3.1 splits as sequence of A-modules (but not,
in general,
canonically), whenever the equivalent conditions (1)-(5"') of Proposition 3 and Corollary 3.1 hold (for any pair of integers n, r
with
r
~
0
such that (1)-(5"') hold, whether or not
is finitely generated) . Proof. trivial.
In this case, if Otherwise,
AAt
t = 0
or a unit, the assertion is
is the direct product of finitely
many discrete valuation rings, and the image of
t
in each of
these is an element of each of the respective maximal ideals. Therefore, an
AAt_module
divisible iff
D
D
is such that every element is t-
is injective as
AAt_module.
sequence (5"'), which is a sequence of 2.
If the ring
Therefore the
AAt_modules, splits.
AAt, the t-adic completion of
A,
is a
finite direct product of discrete valuation rings, then again the conclusion of Remark 1 above holds (whether or not principle ideal domain).
A
is a
487
Bockstein Spectral Sequence 3.
Proposition 3, Corollary 3.1 and Remarks 1 and 2 above
all generalize to the situation of Remark 2 following Theorem 2.
I.e., to the case in which:
A
is a ring with identity,
and we have a long exact sequence of left A-modules: (1) indexed by all the integers (such that the left A-module in each spot indexed by an integer congruent to zero modulo three coincides with the left A-module in the next spot (indexed by an integer congruent to one modulo three), as indicated in the display of the sequence (1».
Then if
is the generalized Bockstein spectral sequence, as defined before Lemma 1 (and as generalized in Remark 2 following Theorem 2), so that e.g., n,r
En, n E 1',
then for every pair of integers
such that r 2:. 0, the conditions (1),
Proposition 3 and (5'),
to
"Em"
"Hm(C*)" to
all integers
if the ring
A
(4),
"~",
And for any integer
is left Noetherian and if
En
is finitely
generated as left A-module, then there exists an integer depending on Example 1.
n Let
(5) of
m); and the last two
observations of Corollary 3.1 then hold. n,
(3),
(5") and (5"') of Corollary 3.1 are all
equivalent (with the notation changes: "Hm(C*/tC*)"
(2),
r
such that all of these conditions hold. A
be a ring with identity and let
element in the center of the ring
A.
Let
t
be an
Tn, n 2:. 0, be an
exact connected sequence of functors on the category of left A-modules and let
M be a left A-module such that multiplication
488 by
Chapter 1 t:M
~
M is injective.
Then we have the long exact sequence
to which Remark 3 above, and Remark 2 following Theorem 2, can be applied to the corresponding generalized Bockstein spectral sequence (as defined in Remark 4 following Theorem 2). Example 2.
Let
X
be a topological space,
set of
let
A
be a ring with identity, and let
X,
an element of the center of the ring
A.
U
Let
be an open sub-
F*
tEA
be
be a cochain
complex of sheaves of left A-modules (indexed by all the integers), such that multiplication by
t:F
n
~ F
n
morphism of sheaves of abelian groups, all integers
is a monon.
Then
we have the long exact sequence of cohomology: n-l t n d --->H n ( X,U,F *) -->H n ( X,U,F *) ->H n ( X,U,F */ tF *) --> d ... , a long exact sequence of A-modules, obeying the "parenthetical modulo three condition", of Remark 3 above, and therefore Remark 2 following Theorem 2, applies. The point of Remark 3 above is that the results of this chapter apply to any appropriate (that is, obeying the "parenthetical modulo three condition") long exact sequence, indexed by all the integers, of left A-modules, whether or not it comes ~
priori from some cochain complex, or whether or not from some
kind of cohomology theory (which is how most applications arise - although not always obviously from a cochain complex
C*
of
left A-modules (although, e.g., Example 2 above can be interpreted as coming from such a cochain complex)). Remark 4.
Suppose, under the hypotheses of Theorem 2, that the
489
Bockstein Spectral Sequence ring
A
is commutative and the cochain complex
is a differential graded A-algebra (i.e., that graded A-algebra, with a unit in d(u)
u v + (_l)deg Uu U d(v),
H*(e*)
whenever
products.
(d ) r
(u)
~
"has cup products";
preserves cup
0 the coboundaries
are an "anti-derivation"; Le.,d(uUv)=
r nE;r
d
r
d (uU v) =
H*(e*/te*), and
Hn(e*) ~ Hn(e*/te*), n E Z,
And, for each integer
n
is also a
u E en, v E em, n,m Ea' ).
is a graded A-algebra, as is
the natural map:
e*
of A-modules
and such that
Then the long exact sequence of cohomology (1) i.e.,
e*
r
(_l)de g Uu U d (v) u E En, v EE m, n,m E a'. r' r r
U v +
fore, by induction on
r,
n n (E r + l , d r + l ) nE1
There-
is a graded (A/tA)-
algebra, and is the cohomology of the differential graded (A/tA)-algebra directly.
This is all easily verified
(I've gone through the simple details myself).
There-
fore we say that the exact couple (2) has cup products, and that the associated generalized Bockstein spectral sequence: also has cup products.
In the more general circumstances of Remark 2 following Theorem 2, one must require that the long exact sequence (1) have cup products in the same sense (i.e., ring,
V*
is a graded A-algebra,
the natural map: V* tion on r, algebra (Er+l)nE;r n
(Er)nE;r ).
E*
n
is a commutative
is a graded A/tA-algebra;
preserves cup products; and by induc-
that the coboundaries
(E )nE7. r
n
~
E *
A
make the graded
into a differential graded algebra, so that
becomes a graded algebra (as the cohomology of In which case, we again say that the long exact
Chapter 1
490
sequence (1) has cup products, that the singly graded exact couple associated to the long exact sequence (1)
(with cup
products) has cup products and that the associated generalized Bockstein spectral sequence:
has cup products. (Note:
In practice, most long exact sequences (1)
usually
can be interpreted as coming from an appropriate cochain complex of left A-modules
C*
is injective, all
n E
such that multiplication by ~.
t:c
n
+
c
n
And when the long exact sequence (1)
"has cup products" in the sense just defined above, then it usually comes from such a cochain complex ential graded A-algebra.
C*
that is a differ-
E.g., this is the case in the situation
of Example 2 of Remark 3, see [RRWG1, Chapter I, last section. Considering the construction of an appropriate cochain complex in that reference, we see in fact that, under the hypotheses of Example 2 of Remark 3 above, if the cochain complex of sheaves of A-modules
F*
over the topological space
X
has the
structure of (0' -indexed) sheaf of differential graded A-algebras then both the singly graded exact couple associated to the long exact sequence of cohomology: dn- l
(1)
t
dn
--->Hn(X,U,F*)-->Hn(X,U,F*)~Hn(X,U,F*/tF*) --> •••
has cup products in the sense of this Remark, and therefore so also does the generalized Bockstein spectral sequence
Bockstein Spectral Sequence
491
associated to this exact couple, as described in this Remark (and defined just preceding Lemma 1). that, in Chapter I, last section of Hn(X,U,F*) = Hn(C*), where of
[~P.WCJ,
C*
see Chapter I, is a
(The reason for this is [~~WC.J,
we note that (3)
C*(X,U,F*), in the notations ~-indexed
differential graded
A-algebra, and the isomorphism (3) preserves cup products (and in fact is the way, in [p.p.we], Chapter I, that we define cup products in
Hn(X,U,F*)
whenever
ential graded A-algebras) and where as graded A-algebras. C*(=C*(X,U,F*»
F*
is a sheaf of differ-
Hn(X,U,F*/tF*) ~ Hn(C*/tC*)
(Note also that the definition of
is such that, if multiplication by
t:F
n
~ F
n
is a monomorphism of abelian groups, then so is multiplication by
t:C
n
~ cn, all integers
definition of C*(X,U,F*)
in
n.
This is immediate from the
[P'p'~CJ,
Chapter I.)
We have shown: Example 2, continued. Remark 3 above, if also
Under the hypotheses of Example 2 of F*
is a sheaf of differential graded
A-algebras, then the singly graded exact couple associated
to
the long exact sequence (1) of Example 2 of Remark 3 has cup products as defined in this Remark (Remark 4), and therefore so does its associated generalized Bockstein spectral sequence (as defined preceding Lemma 1),
("having cup products" as
defined in this Remark, Remark 4). [P.P.W~~,
(The reason being that, by
Chapter I, last section, this reduces to the assertion
about cochain complexes
C*
of A-modules that are differential
graded A-algebras, as discussed at the beginning of this Remark) .
This Page Intentionally Left Blank
CHAPTER 2 THE SHORT EXACT SEQUENCE 1.8.
In this chapter, I recall an exact sequence which I established in an earlier paper, Theorem 1.
Let
A
[P.P.w.cJ, 1.8.1, pgs. 159-160.
be a ring with identity, and
ment in the center of
A.
Let
tEA
an ele-
be a cochain
complex of left A-modules (indexed by all the integers). that (multiplication by n.
n t): C
Then for every integer
->-
n C
Suppose
is injective, all integers
n,
(1)
We have a short exact sequence of
(*)
O-+Hn(C*)J\t-+lim[Hn(C*/tic*)]-+ i>O.
lim (precise -t~-torsion in
~t-modules
1 Hn + (C*»
->-
O.
i>O
(Here M,
"ri't"
e •g • ,
M
denotes the t-adic completion of
= Hn (C *) ) •
in
Hn+l(C*».
~>O
"
(In the inverse system
t.")
there is induced an isomorphism of liml[Hn(c*/tic*)] i~O
dn:Hn(C*/tic*)-+ "(proecise ti-torsion
the maps of the inverse system are all in-
duced by "multiplication by
(2)
i~O,
Hn(C*) -+Hn(C*/tic*),
and the epimorphism by the coboundaries i ~ 0).
all A-modules
(The monomorphism in the exact sequence
(*) is induced by the natural maps:
Hn+l(C*),
M,
Also, for every integer A"t-modules
~~iml(precise ~~O
4093
n,
ti-torsion in
Hn+1(C*».
494
Chapter 2
(Where the isomorphism is induced by the coboundary mappings . +1 d n :H n (C*/t1. c *) ~Hn (C*), i,:,O). For want of a better name, we shall refer to the exact sequence (*) of Theorem 1 and the isomorphism (2) of Theorem 1 as "the exact sequence 1.8". Proof:
The proof is exactly as given in [P.P.W£J, 1.8.1; but we
repeat it. For each integer (~-indexed)
i,:, 0,
the short exact sequence of
cochain complexes of A-modules
gives rise to the long exact cohomology sequence:
n l H + (C*)
-;.
...
from which, for each integer
n,
we extract the short exact
sequences (1)
o~ [Hn(C*)/ti(Hn(C*)) ~Hn(C*/tic*) .... (precise ti-torsion in
The functor
"lim" i>O
Hn + l (C*)) ~ 0,
i > 0.
is a left-exact functor from the cate-
gory of inverse systems of A-modules indexed by the non-negative integers into the category of A-modules. functor is
"liml",
The first derived
and the higher derived functors are zero.
bO If we fix variable
i >
°
n> 0,
then the short exact sequences (1) for
can be thought of as a short sequence of in-
verse systems of A-modules indexed by the non-negative integers.
The Short Exact Sequence 1.8
495
Applying the system of derived functors
lim, liml, 0, i>O i>O to this short exact sequence yIelds an exact sequence
0, ... ,0 .•.
of A-modules with six terms: (2)
O-+Hn(c*)l\t-+lim[Hn(c*/tic*)]-+ i>O lim({precise tl-torsion elements in i>O
Hn+l(C*)})-+
l n Ij,m [H (C*) /ti
i>O i liml ({precise t -torsion elements in i>O all integers system:
n.
n 1 H + (C*) }) -+ 0,
But, in the exact sequence (2), the inverse
(Hn(C*)/t. Hn(C*)) i>O
is an inverse system of A-modules
and epimorphisms, so that (3)
But equation (3) tells us that the fourth group in the exact sequence of six terms (2) is zero.
Therefore, the exact sequence
(2) becomes an exact sequence of three terms (conclusion (1) of this Theorem) and an isomorphism (conclusion (2) of the Theorem). Q.E.D. Corollary 1.1.
Under the hypotheses of Theorem 1, let
arbitrary fixed integer.
n
be an
Then the following conditions are
equivalent:
(1)
The natural map of
Al\t-modules:
Hn (C*)l\t .... lim Hn(C*/tic*)
i"to
(I') The natural monomorphism of
is an isomorphism. (A/tA)-modules:
[(A/tA) ~ Hn(C*)] .... (A/tA) ~ [lim Hn(C*/tic*) 1 A
isomorphism.
A
ito
is an
Chapter 2
496
(2)
The A-module
Hn+l(C*)
has no non-zero infinitely
t-divisible, t-torsion elements. (2') Same as condition (2), with "precise t-torsion" replacing "t-torsion". (3)
Let
u E Hn(C*/t C*)
u, E Hn(C*/tic*),
i ~ 0,
1
that the image of integers
be such that there exist
u i +l
such that in
that the image of
v
is
is
all
ui '
vE:Hn(C*)
H (C*/t C*)
in
and such
= u
l Hn(C*/tic*)
Then there exists
i > l.
u
such
u.
Before proving Corollary 1.1, we state and prove two related Lemmas. Lemma 1.1.1. ger
n
Under the hypotheses of Theorem 1, for every inte-
we have a short exact sequence of
(* .1)
0 .... [(A/tA)
(A/tA)-modules
~ Hn (C*)] - - - -...., (A/tA) ~ [lim Hn (c*/tic*)] A
i~O
A
.... (precise t-torsion in
Hn+l(C*)
that is in-
finitely t-divisible) .... O. More generally, for every integer
n E'2
we have a short exact sequence of
(A/tjA)-modules
(*.j)
and every integer
j
~
0 .... [(A/tjA) ®Hn(C*)] .... (A/2lV ® [lim Hn(C*/tic*)] A
A
.... (precise tj-torsion in
i>O
Hn+l(C*)
that is in-
finitely t-divisible) .... O. Remark:
The inverse limit of the short exact sequences (*.j)
of Lemma 1.1.1 for
j
~
0
is the short exact sequence (*) of
Theorem 1. Lemma 1.1.2.
Under the hypotheses of Theorem 1, for each inte-
0,
The Short Exact Sequence 1.8 ger
n E 'Z,
the natural map of (A/tA)
(A/tA) -modules:
[lim Hn(C*/tiC*)]->-Hn(C*/tC*) A i>O
@
is a monomorphism. every integer
497
More generally, for each integer
j~O,
the map of
n E'Z
and
(A/tjA)-modules:
(A/tjA) ® [lj,m Hn(C*/tiC*)]->-Hn(C*/tjc*) A i>O is a monomorphism. Proof of Lemma 1.1.1:
Regard every left A-module as a module
over the polynomial ring ring 'Z
as
'Z
'Z[T]
in one variable
of integers, by letting 'Z[T]-module by letting
left A-module
M,
"T"
"T"
act as
T "tn.
act as zero.
over the Also regard
Then for any
we have that
M ® 'Z "" M/tM"" (A/tA) ® M 'Z[T] A and
TorI [T] (M,.?) "" (precise t-torsion in
Notice also that if
D
M).
is the third group in the short exact
sequence (*) of Theorem 1, then
D
has no non-zero t-torsion.
Otherwise stated, (1)
TorI [T] (D,'Z) = O.
Therefore if we throw the short exact sequence (*) of Theorem 1 through the system of derived functors: on the category of
TOr{ [T] ( ,'Z),
k ~ 0,
7 [T]-modules, then the last three terms of
the resulting long exact sequence become the short exact sequence (*.1) claimed in the Lemma.
(The fourth-from-the-last
term in the long exact sequence is zero by equation (1).) establishes the short exact sequence (*.1).
This
Applying (*.1),
Chapter 2
498
with
t
j
replacing
t,
we see that (*.j) follows from (*.1). Q.E.D.
Proof of Lemma 1.1.2.
Consider the commutative diagram with
exact rows: 0->- [(AltA)
~Hn (C*) 1 --.;;,
Ii
n H (C*/tC*) ->- (precise t-torsion in
r
n
n
Hn+l (C*)) ->- 0
r
i
0->- [(AltA) @H (C*) 1 -+ (AltA) @ [lj:m H (C* It C*) 1 ->- (precise t-torsion in A A PO Hn+l (C*)- that is infinitely t-divisible) ->- O.
The top short exact sequence is the short exact sequence occurring in equation (1) of the proof of Theorem 1, in the special case
i = 1.
The bottom short exact sequence in this diagram is
the short exact sequence (*.1) of Lemma 1.1.1.
The first and
third vertical maps in the above diagram are, respectively, an identity map and an inclusion map, and are therefore monomorphisms.
But then, by the Five Lemma, it follows that the middle
vertical map in the diagram is a monomorphism. first assertion of Lemma 1.1.2; replacing the second assertion, for each integer Proof of Corollary 1.1:
t
This proves the by
t
j
then proves
j ,:,,1.
Clearly, the last group in the short
exact sequence (*) of Theorem 1, is zero iff condition (2') holds.
Therefore condition (1) of Corollary 1.1 is equivalent
to condition (2') of Corollary 1.1.
Similarly, the last group
in the short exact sequence (*.1) of Lemma 1.1.1 is zero iff condition (2') holds.
Therefore condition (I') of the Corollary
is equivalent to condition (2') of the Corollary.
Also it is
obvious that conditions (2) and (2') of the Corollary are equivalent (since if there exists a non-zero t-torsion element
u
The Short Exact Sequence 1.8
499
that is infinitely t-divisible, then choose i > 0 such that i i+l i t ·u=O, t·u;iO. Then t • u is a non-zero precise ttorsion element that is infinitely t-divisible).
Therefore
conditions (1), (1'), (2) and (2') of the Corollary are equivalent. On the other hand, condition (3) asserts that if
I
is
the image of the natural map: n Hn (C*) .... [lim H (c*/tic*)], i< 0
(1)
I,
then the image of in
Hn(C*/tC*),
and of the right side of equation (1),
are the same.
But since
(A/tA)-module, the natural homomorphism: Hn(C*/tC*) (2)
Hn(C*/tC*)
is an
[lim Hn(C*/tiC*)] .... i>O
can be factored: n [lim Hn (C*/tic*)] .... (A/tA) ® [lim H (C*/tic*) 1 ....
ito
A
i>O
But by Lemma 1.1.2, the second map in equation (2) is a monomorphism.
Therefore, condition (3) of Corollary 1.1 is equivalent
to the assertion that, the images of
I
and of the right side
of equation (1) under the first map of equation (2), coincide. But since the image of the right side of equation (1)
under the
first map of equation (2) is the whole of (A/tA) ® [lim Hn(C*/tic*)] A
we see that condition (3) of the Corol-
i>O
lary is equivalent to the assertion that the natural mapping of (A/tA) -modules: (3)
[(A/tA) ® Hn (C*)] .... (A/tA) A
is an epimorphism.
@
A
n [lim H (C*/tiC*)] itO
The mapping (3) is the first mapping in the
500
Chapter 2
short exact sequence (*.1) of Lemma 1.1.1, and therefore is always a monomorphism.
Therefore, condition (3) of the Corol-
lary is equivalent to the assertion that the above displayed mapping (3) is an isomorphism.
But this latter assertion is
condition (1') of the Corollary.
Therefore condition (3) of the
Corollary is equivalent to condition (1') of the Corollary, completing the proof. Remarks.
1.
The reader should notice that, in both conclusions
(1) and (2) of Theorem 1, the inverse system: sion elements in , by t~on
Hn+l(C*)}),
~>O
has for its maps, "multiplica-
, -, 1 ements ~n ' t"{ : prec~se t i+l -tors~on-e
{precise ti-torsion elements in 2.
In
({precise ti-tor-
Hn + l (C*) },
Hn+l(C*)}->each integer
i > O.
[P.P.WCJ, 1.8.1, we left the statement of the
Theorem as the exact sequence of six terms, equation (2) in the proof of Theorem 1.
It is, of course, trivial to go from this
sequence to the slightly improved conclusion (equations (1) and (2) of the conclusion of Theorem 1 above). 3.
The reader will notice that the proof of Theorem
1 would work with any suitable "cohomology theory" replacing the cohomology of cochain complexes. Example 1.
Let
A
obeys Axiom (P.l) Let from
Tn, A
n E 71, into
and
S
be abelian categories, such that
(see Introduction, Chapter 1, section 7). be any exact connected sequence of functors
S.
an endomorphism of
Let M
MEA in
A
be an object and let
o ->- Tn (M) At ->- lim i~O
Tn (M/tiM) ->-
lim (precise ti-torsion in
i~O
t:M ->- M
that is a monomorphism.
obtain a short exact sequence: (1)
a
Tn + l (M»
->- 0
be
Then we
The Short Exact Sequence 1.8
501
and an isomorphism (2)
· 1 Tn (M/ t i M) "" 1 ~m .... l '~m 1
i!O
all integers
( prec~se . ti
(Here,
n.
bl
"Tn (M) At"
Let
center of
A
and "(precise ti-torsion in
A
be a ring, let
and let
F*
t
til: Fn .... F n
groups, all integers
be an element of the
be a cochain complex of sheaves of
x.
A-modules over a topological space cation by
denotes as usual
"Ker(Tn+l(t i »".)
denotes
Example 2.
T n + l (M»,
. ~n
i>O
"l~m(eoker(Tn(ti):Tn(M) .... Tn(M»)" Tn~l(M»"
. -tors~on
Suppose that "multipli-
is a monomorphism of sheaves of abelian
n.
Let
U
be any open subset of
x.
Then we have a short exact sequence (1)
O .... Hn(X,U,F*)At+lj,m Hn(X,U,F*/tiF*) .... i> 0 lim {precise ti-torsion elements in i>O
Hn+l(X,U,F*)} .... 0,
and an isomorphism (2)
liml Hn(X,U,F*/tiF*)~ liml (precise ti-torsion in i>O i!O Hn+l(X,U,F*»,
all integers
n.
Does Theorem 1 generalize to abelian categories? Theorem I'.
Let
A
Yes.
be an abelian category such that denumerable
direct products exist, and such that the direct product of a denumerable set of epimorphisms is an epimorphism (i.e., such that the fUnctor "denumerable direct product" preserves epimorphisms). Then let A
e*
be any cochain complex of objects and maps in
(indexed by all the integers), and let
endomorphism of the cochain complex
e*
t*: e* .... e* such that
t.e any
tn: en .... en
Chapter 2
502
is a monomorphism, all integers
n.
Then for every integer
(1)
We have a short exact sequence
(*)
O-+Hn(c*)At-+lj,m [Hn(C*/(t*)i C*)]-+ i>O IJ,m (precise ti-torsion in i>O
(where by
"C*/(t*)ic *"
"Coker [(t*)i: C*-+C*]",
n
n l H + (C*)) ... 0,
we mean the cochain complex: we mean
and by
"lim [Coker(Hn((t*)i): Hn(C*) -+Hn(C*))]", i>O
and where "precise
ti-torsion" is defined as in the Definition in Chapter 1, Remark 4 following Theorem 2, and also in the Introduction), and for every integer
n
we have an isomorphism
liml[Hn(C*/(t*)ic*)],! i>O
(2)
lim (precise ti-torsion in i>0 Proof:
Hn+l(C*)).
The hypotheses on the abelian category
A are necessary
and sufficient for
A
"lim" to exist for all inverse systems in i>0 indexed by a denumerable directed set not having a maximal
element, for cally zero.
l "lim "
2
"1j,m " to be identii>O Therefore the proof of Theorem-l generalizes to
{to
to exist, and for
prove Theorem I'. (*) 4.
After a suitable modification in the statement of
Theorem 1 (or of Theorem I'), can the hypothesis that "multiplication by
t"
(or that the map
tn)
be a monomorphism: Cn -+ cn,
(*) For a description of the elementary properties of an abelian category A obeying the indicated conditions, see the Introduction, Chapter l. se,ction 7.
The Short Exact Sequence 1.8 all integers question in
n,
be removed?
Theore~2
503
The answer (as in the analogous
and 2' of Chapter 1) is "yes".
We state
the more general theorem, first at the abelian-category theoretic level (as it is no harder in this case) and then, in Remark 5 below, in the more concrete situation of a cochain complex of A-modules. Theorem 2'.
Let
A be an abelian category such that denumerable
direct products of objects exist, and such that the denumerable direct product of epimorphisms is an epimorphism (i.e., such that the functor "denumerable direct product" preserves epimorphisms). gory
A
Let
C*
and let
cochain complex
be an arbitrary cochain complex in the catet*: C* .... C* C*.
For each integer plex
D~ l
l
1 , = C~l x C~+ l
d~:D~ .... D~+l d~(u,v)
i> 0,
in the category
D~
be an arbitrary endomorphism of the
define a
A
(;r-indexed) cochain com-
as follows:
and the coboundary:
is the map such that, in terms of elements [I.A.C.]
= (dn(u) +"(t*)i,,(V), _dn+l(v)).
l
chain complex
t*
of the
phism
"t*"
of
D~ l
is the co-
constructed in the proof of Theorem 2' of
0*
Chapter I, but with the i'th iterate phism
(Thus,
~ochain
C*
complex
C*
"(t*)i"
of the endomor-
replacing the endomor-
in that construction).
Then, the notations
being as in Theorems 1 and I', (1)
For each integer
n
we have the short exact sequence
in the abelian category (*)
A:
504
Chapter 2 lim (precise ti-torsion in i>O
Hn + l (C*)) + 0,
and the isomorphism
Proof: i
~
0,
Hn
lim i~O
(2)
(D~) ~ lim ~
n H + l ((C*).
(precise ti-torsion in
i>O
As in the proof of Theorem 2' of Chapter 1, for each we have a short exact sequence of cochain complexes: O+C*+Di+C*(+l) +0,
(where
. ~s
C*( + 1)
t he
. cocha~n
and with n I th coboundary
comp 1 ex such t h at
- d!l+ 1 , n E 7! ,
Cn(+l) __
cn +l
,
which as in the proof
of Theorem 2' of Chapter 1 gives rise to a long exact cohomology sequence of the form:
Hn + l (C*) -;:.
(In this long exact sequence, as in the proof of Theorem 2' of Chapter 1, the map labelled a&
"Hn((t*)i)"
is the (n-l) 'st
coboundary for the indicated short exact sequence of cochain complexes, and is explicitly computed to be the map n H - l (C* (+1»
after we identify other maps).
n
= H (C*).
Hn ( (t*) i) ,
Similarly for the
The proof of Theorem 2' then closely folIDWS that
of Theorem 1', with the long exact sequences,
i
~
0,
just con-
structed taking the place of the corresponding long exact sequences, Remark 5. Theorem 2.
i
~
0,
used in the proof of Theorem 1'.
An important special case of Theorem 2' is Let
A
be a ring with identity and let
an element in the center of the ring
A
t E: A
be
that is not a divisor
The Short Exact Sequence 1.8 of zero.
Let
C*
be an arbitrary cochain complex of A-modules
(indexed by all the integers).
01
505
For each integer
i
~
0,
let
be anyone of the following cochain complexes: (1)
01 =
('c*)/ti(,c*),
where
'C*
is any (;z'-indexed)
cochain complex of A-modules such that "multiplication by 'C
n
-+ 'C
n
is inj ecti ve, all integers
n,
and where we have a
fixed map of cochain complexes of A-modules Hn {¢*): Hn(,C*) -+Hn(C*)
that n.
(Such
a
'C*,
¢*
ttl:
¢*:
'C* -+ C*
such
is an isomorphism, all integers
exists, as is easy to see - we have
made this construction in the footnote to Remark 4 following Theorem 2 of Chapter 1), or (2)
O~
~
=
F~
~
@C*,
where
A
F~
is a
~
(non-positively indexed)
cochain complex constructed as follows: be any acyclic, flat (e.g., projective), homolo-
Let
gical resolution of the right A-module Ft
~
A/tiA,
and then let
be the corresponding (non-po£itively indexed) cochain com-
plex such that
F~ = pi ~
-n'
n
~;z'.
pi = 0
(E.g., one can take
n
to be "multiplication by (3)
where
'C*
o~ ~
=
F~ @ ( ' ~A
and
¢*:
till),
or
C*) , 'C* -+C*
are as in (I) above, and the non-
positively indexed cochain complex Then for each integer (I)
and
'
F~
~
is as in (2) above.
n,
We have a short exact sequence of
~t-modules
506
Chapter 2 n
O .... H (C*)
(* )
At
. n .... It-m [H i>O
(D~)l l
....
Hn + l (C*)) .... 0
lim (precise ti-torsion in i>O and an isomorphism (2)
Proof:
The proof is similar to that of the footnote to Remark
4 following Theorem 2 of Chapter 1. fine
Indeed, if we were to de-
as in Remark 4 above of this chapter,
"D~" l
(let's call
this Definition (0)), instead of using Definition (I), (2) or (3), then Theorem 2 becomes Theorem 2' of Remark 4 of this chapter.
It remains to show that Definitions (I), (2) or (3)
above yield cochain complexes
D~ l
having the same cohomology
as that using Definition (0).
But the
nD~" l
of Definition (3)
maps into that of Definition (2), and by the Kunneth relations (since each
F
n
Similarly, the
is flat over "D~n
A)
has the same cohomology.
of Definition (3) maps into that of Defi-
l
(F* ® 'C* .... (A/tiA) l~ 'C*), and since "multiplication A A n n 'C .... 'C is injective (or equivalently, since
nition (1) by
tin:
Tor~(A/tiA, 'C n ) J
i
A
Tor. (A/t A, ) J
_
= 0,
= 0,
all integers j
~
2,
since
j t
~1
(of course,
is a non-zero divisor)),
again the usual Kunneth relations spectral sequence implies that this map induces as isomorphism on cohomology. nitions (1), (2) and (3) oE the same cohomology groups. tion (1)
D~ l
Thus, Defi-
give cochain complexes having
Also, this shows that in Defini-
(or (2), or (3)), the cohomology of
Di'
is indepen-
dent of the arbitrary choices (in Definition (I), of a suitable 'C*
and
~*i
in Definition (2), of
P*i
in Definition (3),
The Short Exact Sequence 1.8 of both of these).
507
To complete the proof that [Theorem 2' of
Remark 4 above of this chapter implies Theorem 2 above], it suffices to show that
using Definition (0)
(i. e.,
as de-
fined in Theorem 2' of Remark 4 of this chapter) has the same cohomology as
Di
using Definition (2).
is a non-zero divisor,
But in fact, since
t
(as in the footnote to Remark 4 follow-
ing Theorem 2 of Chapter 1 with
t
i
replacing
t)
in Defini-
i p*,
tion (2) we can take for flat resolution the projective i t i resolution -+ 0 -+ 0 -+ A---'»A -r A/t A .... 0 of the right A-module A/tiA.
But then (as observed in the footnote to Remark 4 fol-
lowing Theorem 2 of Chapter 1, with
t
i
replacing
Definition (0). Q.E.D. (Remark:
as
D'!'
1.
as defined in
D~ 1.
defined in Definition (2) coincides with
t),
(For details, see "percohomoloqy", Chap. 5).
In the proof of Theorem 2' of Remark 4, one has
to compute explicitly the map: that this map is
Hn«t*)i).
Hn-l(C*(+l)) -+Hn(C*)
and show
This is not difficult, going back
to the explicit construction of the coboundary in the cohomology sequence of a short exact sequence of cochain complexes.
But
there is an alternative way, using Theorem 2 and [I.A.C.), analogously
to our last observation in the footnote to Remark 5 fol-
lowing Theorem 2 of Chapter 1. Namely, first suppose that the hypotheses are as in Theorem 2 of Remark 5 of this chapter; to prove that the long exact cohomology sequence of Theorem 2' has the indicated form.
In
fact, in the proof of Theorem 2 of thi& chapter, we have shown that Definitions (I), (2) and (3) of isomorphic cohomology.
all have canonically
And (as in the proof of Theorem 2 of
Remark 5 of this chapter) the construction
D~ 1.
of Theorem 2'
Chapter 2
508
in the terminology of the proof of D*" i ' Theorem 2 of Remark 5 of this chapter) is a special case of i ti i Definition (2) (when P*= ... O+O+A ->A+A/t A-+O). There("Definition (0) of
fore, to prove the assertion under the hypotheses of Theorem 2, it suffices to prove the analogous assertion with, e.g., Definition (1) of
D'i!'. ~
the exact
But under Definition (1) of
sequence (1) and isomorphism (2) in the conclusion of Theorem 2 follows from Theorem 1 applied to the cochain complex of A-modules
'C*.
This proves the assertion under the hypotheses of
Theorem 2 of Remark 5 of this chapter.
Finally, knowing Theo-
rem 2' of Remark 4 of this chapter is true in the case A = the category of A-modules,
A
phism "multiplication by the center of
A
a ring, and t",
t
t*: C*-+C* = the endomor-
a non-zero divisor in
A
in
(i.e., under the hypotheses of Theorem 2 of
this chapter), implies Theorem 2' of Remark 4 of this chapter in general, by using the Exact Imbedding Theorem,
[I.A.C.]
(by the
same argument as in the last portion of the footnote to Remark 4 following Theorem 2 of Chapter 1». Remark 6. chains? Theorem.
Can Theorem 2' of Remark 4 be generalized beyond coYes. Let
A
and
B
be abelian categories.
denumerable direct products exist in the category
Suppose that B,
and that
the denumerable direct product of epimorphisms in the category B
is an epimorphism (that is, that the functor "denumerable
direct product" is an exact functor in
B).
Let
ColA)
be the
abelian category having for objects all cochain complexes (indexed by all the integers) of objects and maps in the abelian category
A,
and all maps of such cochain comlexes.
If
The Short Exact Sequence 1.B F* ECo(A)
and if
O*=O*(t*,F*)
t*:F* ->F*
is an endomorphism, then define
to be the object of
CoCA)
cochain complex of objects and maps of
d all
n
(i.e., the
is
(in terms of ele-
the map
n n+l (u,v) = (d (u) + t* (v) , - d (v»
UE:Fn,
VE:Fn+l,
nE:7.
Also, if
,
F*ECo(A)
F* (+1) E: Co (A) to be the cochain complex such that all integers Fn+l(+l)
n,
F*(+l)
n n F + l ->F + 2
(n+l) ' s t coboundary:
(I.e., roughly speaking,
is the negative of the
in the cochain complex
F*(+l)
is
F*
n E 7,
abelian category
C,
F* E C,
1
C into the
and let i
t* :F* -> F*
~
n
E~)
is a map in
"F* C
shifted by of
in the category (+1) = tn+l,
C,
is an object in the subcategory F* ->
(the maps in
o~ 1
F n -> F n x Fn+l,
such that the cochain complex
+1", is also an object in the sub-
Co (A), such that the map, Co(A)
be any
the cochain com-
0,
whose n' th coordinate is the inclusion:
category
n
Let
C, such that, for each integer
F*(+l),
t
B.
and such that the inclusion map:
all
CoCA)
be any cohomological exact connected se-
O'ii=O*((t*)i,p*) E:Co(A)
Co (A)
F*.
"shifted by +1").
quence of functors from the abelian category
plex
Fn(+l)->
C be any exact, abelian subcategory of
and let
map in
then define F n (+1) = pn+l,
and such that the n'th coboundary:
in the cochain complex
Now let
7-indexed
A) such that
dn:O n -> on+l
and such that the coboundary ments, see [I.A.C.])
509
t* (+1) :F* (+1) .... F* (+1),
lies in the subcategory
all integers
n),
C
(where
such that the map in
Co (A) ,
Chapter 2
1510
"t* xt*(+1)":05 ->-05 a map in in
C,
Co(A),
such that for each integer call it
is the map: F n x F n+l
(whose n'th coordinate is tnx(tn(+l»)
"(1 xt*)i",
(identity F
->-
i.:: 1;
x «n+l) I st coordinate of
n
Co(A)
projection:
F n x F n + l ->- F n + l ,
category
of
C
"(1 x t *) i
gers
n.
nE;??,
t*):
• 1S a map 1n
II'
n E;r)
c,
is a map in the sub-
Tn (05) = 0,
(**)
n H (05) = 0,
all integers (1)
so this last condition will hold if, whenever Hn (G*) = 0,
0t-l
whose n'th coordinate is the
all
It is easy to see that
that
->-
Co(A).
Suppose also that mark:
ot
and such that the proj ection map:
(the map in
°t->-F*(+l)
the map
whose n'th coordinate,
Fn x F n + , l .1S SUC h t h at
all integers
i >1
is
all integers
n, then
n.
(Re-
all integers G* E C
Tn (G*) = 0,
Most exact connected sequences
n,
is such all intethat one
comes across in practice have this latter property, and therefore a fortiori are such that condition (**) holds for any such
F* E C ). Then for every integer
sequence in the category (1)
o ->-T n (F*)l\t*
n
B:
->-lim Tn(O*)
i>O
there is induced a short exact
->-
1
lim (precise (t*) i-torsion part of
Tn + l (F*)) ... 0
i>O and an isomorphism in
B:
(1) To show this, by the Exact Imbedding Theorem [I.A.C.] it suffices to prove in the case that A = category of abelian groups, C = all of Co (A). But then, we have seen in the footnote to Remark 4 following Theorem 2 of Chapter 1 (in the special case t = 1) that Hn (OB*) '" Hn (C* /1 • C*) = 0, all integers n. (Use Definition (1) of *(=0 of that footnote, with 'C*=C*, <jJ*=identityof C*).
0)
The Short Exact Sequence 1.8
511
(2)
(Here, as usual, eg., "Tn(F*)At*"
Proof:
"lim (Coker(Tn«t*)i):Tn(F*) ->-Tn(F*)))". i>O
First, for each integer
sequence in (* i)
denotes
0 ->- F*
Co(A),
-7
and in
Dt ->- F* (+1) ->- 0,
i = 0,
by hypotheses
we have the short exact
C, which yields the long exact
sequence in the category
For
i >0
(**),
B:
Tn(D
O)
=
all integers
0,
Therefore, from the long exact sequence (1 ), 0 the
n.
we deduce that
(n-l) 'st coboundary is a canonical isomorphism:
(2)
Tn-1(F*(+1)) :;Tn(F*)
in the category
all integers
B,
Next, observe that we have a commutative diagram with exact rows in the category
Co(A),
1 ft
and also in
C,
0 +F* ->-Dt ->- F*(+l)->-O
(3)
(identity)
0->- F* ... where
(t*(+l))i
t*(+l)
of
D~
~
l(t*(+l))i ->- F* (+1) ->- 0
denotes the i'th iterate of the endomorphism
F*(+l)
in
C,
and where
P!:D! +D(l
is the com-
posite of the mappings: "(lxt*)," Di
~>D!_l
"(lxt*)i_l"
>D!_2~···
" (1 x t*) "
1) D*
o
n.
Chapter 2
512
in the category
C.
The diagram (3) yields a map from the long
exact sequence (li) into the long exact sequence (1 ), all in0 tegers
i > O.
The portion about the (n-l) 'st coboundaries is
B:
the commutative square in the category
(4)
where the bottom isomorphism is the isomorphism (2), and where is the (n-l)'st coboundary of
the top map, labeled the long exact sequence (li)
(of the short exact sequence (*i».
Therefore, by the diagram (4) and the isomorphism (2), if for every integer
n
we identify the objects
B
Tn(F*) in the category
Tn-l(F*(+l»
and
by means of the canonical isomorphism
(2), then the (n-l)'st coboundary in the long exact sequence (li) is identified to the endomorphism (5)
Tn-l«t*(+l»i)
of
Tn-l(F*(+l»,
all integers
n.
But we also have a commutative diagram with exact rows in the category
Co (A),
1
and in the category
C,
O--l>F*-:>DCi ---------':>F* (+1) (6)
t*
l't* x t* (+1)"
0-> F*--l>D*
o
:>0
}* (+1) :> F* (+1) - > 0
where each of the rows is the short exact sequence (*0).
This
gives rise to an endomorphism of the long exact sequence (1 ), 0 and considering the portion of (1 ) around the (n-1) 'st co0
The Short Exact Sequence 1.8
513
boundary, to the commutative square: Tn-l(F*(+l))
,., i>Tn(F*)
Tn-l(t*(+l))l
(7)
Tn - l (F* (+1))
lTn(t*) ,., i> Tn (F*)
in which the horizontal isomorphisms are the isomorphisms (2). Since we made the isomorphisms (2) into identifications, it follows that, under the identification Tn-l(t*(+l)) Tn(t*)
of
of
Tn-l(F*(+l))
Tn(F*).
(2~,
the endomorphism:
corresponds to the endomorphism
Hence similarly for the i'th iterates.
Considering observation (5), it follows that, if we identify Tn-l(F*(+l))
and
all integers
n,
Tn(F*)
by means of the isomorphism (2) for
then the (n-l) 'st coboundary in the long
exact sequence (Ii) is identified to the endomorphism of the obj ect all integers
Tn (F*) n.
in the category
B,
Tn«t*)i)
all integers
i.:: 0,
But then the long exact sequence (Ii) is
identified with a long exact sequence
all integers
i > O.
Using the map
"(1 x t*) i+l",
map from the short exact sequence (*i+l) sequence (*i)
in the category
exact sequence (li+l) category
B.
it is the map map
C,
we obtain a
into the short exact
and therefore from the long
into the long exact sequence (Ii) in the
(This map is such that, "along the first "Tn(t*)";
"identity"· Tn (F*) ,
"Tn("(1xt*)i+l")",
"along the second
Tn(F*)",
Tn(F*)", it is the
and "along
all integers
Then using the long exact sequences
n) ,
all integers
(1i)'
i .:. 0,
i > O.
and the map
514
Chapter 2
of long exact sequences from (li+l) ly constructed, all integers
i
(i~O)
long exact sequences
~
into
(li)
just explicit-
0, in lieu of the corresponding
and maps of long exact sequences
used in the proof of Theorem 1, we now obtain similarly (and just as easily) the two conclusions,
(1) and (2), of the TheoQ.E.D.
rem. Example 1.
Let
subset of
X let
X,
be a topological space, let A
U
be an open
be a ring with identity and let
be an element in the center of the ring
A
sarily be a non-zero divisor).
be any cochain complex
of left A-modules over G!
F*
need not neces-
and for each integer
X,
i >0
let
be the cochain complex of sheaves of left A-modules over
G~
such that
0=
the coboundary Ex, x
n u E Fx
the image of ment
Let
(t
tEA
F n )( Fn+l,
all integers
dn:Gr: .... Gr:+ l
and
l
l
n+l v E Fx
(u,v)
Then for every integer sequence of
and such that the
is the map such that, whenever (the stalks at
in the stalk at
(d n (u) + tiv, _d n + l (v) ),
n,
X
x
of
all integers n,
we have that
x) ,
Gn + l
is the ele-
n.
there is induced a short exact
Al\t = (=t-adic completion of
A) -modules:
(1)
Hn + l
->-lim {precise t -torsion elements in i>O
(X,U,F*)}
.... 0,
and for each integer
n
we have an isomorphism of
Al\t-modules
(2)
liml {precise ti-torsion elements in i;:O
Hn+l(X,U,F*)}.
The Short Exact Sequence 1.B Proof:
Take
515
A = category of all sheaves of A-modules over the
topological space whole category
X,
B = category of all A-modules, and
CoCA)
n E 6"',
nected sequence of functors from hypercohomology":
to be the exact con-
CoCA)
Tn(F*) =Hn(X,U,F*),
C = the
into
B,
"relative
all integers
n.
Then
the hypotheses of the Theorem in Remark 6 above are all obviously satisfied.
(The only one requiring verification is (**);
and this follows for the parenthetical reason given following the statement of (**) - that is, if the cohomology sheaves
Hn(K*)
K* E CoCA)
are all zero, all integers
then the relative hypercohomology groups: are zero, all integers made directly.
is such that
Hn(X,U,K*)
n,
(=Tn(K*»
n-and this latter observation is easily
(Notice that if the cochain complex
bounded below, i.e., if
n K = 0, all
n < N,
3 N E6"',
K*
is
then this
also follows from the second spectral sequence of relative hypercohomology.}) mology
(Note that in Example 1 the relative hypercoho-
Hn(X,U,F*),
C* (X,U,F*)
nEl',
does come from a cochain complex
(e.g., use "Godement cochains" as I define them in
[P.RWCJ, Chapter I,---or, if our "punctual cochains").
X
is punctual ([P.P.WCJ, Chapter I),
Therefore, Theorem 2' of Remark 4 (or
even Theorem 2 of Remark 5) can be used, if one wishes, in lieu of the Theorem of Remark 6, to cover the case of relative hypercohomology and an endomorphism of a cochain complex of sheaves that is not a monomorphism.
I prefer the Theorem in Remark 6
since it does not necessitate making use of cochains). Remark 7.
Of course, under the hypohtheses of Example 1, or of
Theorem 1', of Remark 3; or of Theorem 2' of Remark 4: or of Theorem 2 of Remark 5; or, respectively, of the Theorem of Re-
516
Chapter 2
mark 6, then of course we have a Corollary with three equivalent conditions analogous to Corollary 1.1.
(The formulation
is obvious and left to the reader in each case, and of course the proof that 1.1.
(1)~(2)
exactly duplicates that of Corollary
Similarly for the statement of condition (3) and the
proof that
(l)~
(3), in all cases except in "abelian category
theoretic" ones, that is, in all cases except Theorem I' of Remark 3, Theorem 2' of Remark 4, and the Theorem of Remark 6. However, in these cases condition (3) can also be stated (e.g.,
in the Corollary 1.1' to Theorem 1', it reads "the images of the natural mappings:
n n H (C*) -+ H (C* /tC*),
and
coincide"), and it is not
[lim (Hn(C*/tiC*))]-+Hn(C*/tC*),
i>O too difficult to prove once again that essentially the same as in
(1)~(3)
(the proof is
Corollary 1.1; again, the objects on
both sides of the map of condition (1) are "complete", in the sense that N "" lim N/tiN
i>l for each of these objects duced by condition
t*i
N,
were h
i.::. O.
all integers
uti
II
denotes the map in-
One proves that, under
(3), the map in condition (1) induces an isomorphism
"after taking modulo
till
(i.e., after, e.g., for the first
object in the map of condition (1) forming "Coker (H n «t*) i): n H (C*) -+ Hn (C*) ) ") ) • Remark 8.
i >0
Under the hypotheses of Theorem 1 for each integer
the hypotheses of Theorem 2 of Chapter 1
non-negative integer
i,
let
(En (t i ) d n )
r
' r n(:;;?1
r>O
hold. and
For each
The Short Exact Sequence 1.8 (E n
( i)) t nE&,,'
CL
517
denote the generalized Bockstein spectral se-
quenc~
and the Ero-term as described in Theorem 2 of Chapter 1, for i the cochain complex C* and for the element t E A (which is
in the center of ti:C
n
-+ en
A,
and is such that multiplication by
in injective, all integers
n).
Then by the conclu-
sion of Theorem 2 of Chapter 1, for each integer
i::: 0,
we
have the short exact sequence (1)
i 0-+ (A/tiA) ® [Hn(C*)/(t-torsion))-+En(t )-+ 00
A
{precise ti-torsion elements in t-divisible} -+
Hn+l(C*)
that are
o.
The long exact cohomology sequence, the exact couple and the generalized
Bockstein spectral sequence described in Theo-
rem 2 of Chapter 1 for the cochain complex t i +l E A
and the element
each admits a map into the corresponding datum for
cochain complex i::: 0).
C*
C*
and the element
ti EA
Therefore, if we fix the integer
n
(all integers and let
i
vary
through the non-negative integers, then the short exact sequences
(1) define a single short exact sequence of inverse
systems, indexed by the non-negative integers, of A-modules fact, of
At A -modules).
(in
As in the proof of Theorem 1, if we
throw this short exact sequence through the system of derived functors,
lim,
i>O
, 1 I -tm ,
0,0, ••• ,0, ••• ,
then we obtain a short
i>O
exact sequence and an isomorphism, for each integer
n.
We
have proved CorollarLl:..:1..
(Inverse limit of the generalized Bockstein
"abutments" ). Under the hypotheses of Theorem 1, let n E Z,
denote the "abutment" (i.e.,
E~ (t i
),
Eoo-term) of the generalized
Chapter 2
518
Bockstein spectral sequence, as defined in Chapter 1, Theorem 2, corresponding to the cochain complex of A-modules:
the element:
t
i
E A,
non-negative integer
i > O.
all integers En(ti)
i,
00
is the
C*
and
(That is, for each E -term 00
of the gen-
eralized Bockstein spectral sequence corresponding to the long exact cohomology sequence: n-l i n i d_ _ >H n (C*) _t_> Hn (C*) -+ Hn (C* /tic*) ...£-H n + 1 (C*) i..;. ... ) . Then for every integer (1)
n,
there is induced
A short exact sequence of
AAt-modules
(*)
lim{precise ti-torsion elements in i>O and for every integer
n
Hn+l(C*)} -+0,
there is induced an isomorphism of
A" t-modules (2)
that are t-divisible}. Proof:
The observation immediately preceding the statement of
the Corollary
prove equation (2) of the conclusion of the Corol-
lary, and also establish a short exact sequence similar to (*), except that the third group in the sequence is l!m{precise ti-torsion elements in i>O t-divisible},
Hn+l(C*)
that are
rather than the one occurring in conclusion (*) of the Corollary.
However, obviously
The Short Exact Sequence 1.8
519
Hn+l(C*)} ~
lim{precise ti-torsion elements in
i>O
l~m{precise ti-torsion elements in
Hn+l(C*)
that are
i>O t-di visible} , and in fact these groups are also isomorphic to lim{precise ti-torsion elements in ij;"O finitely t-divisible}.
Hn+l(C*)
that are in-
(Since, in e.g., the inverse system ({precise ti-torsion elements in
Hn+l(C*)})i>O'
ments in
Hn + l (C*) l .... {precise ti-torsion elements in
is "multiplication by
the map:
{precise ti+l-torsion ele-
~
i
t", all integers
0).
Hn + l (C*)}
This proves
the Corollary. Notes 1.
Let
tity and let
M be an A-module, where tEA
be any element.
M
for the t-adic topology in the A-module M}.
is a ring with iden-
Then one can define the
topological t-torsion in the A-module
elements in
A
to be the closure, M,
of
{t-torsion
(This definition can be generalized to abelian
categories such that denumerable direct products exist:
M
If
is an object of an abelian category such that denumerable
direct products exist, and if M in the abelian category
A,
t:M .... M is any endomorphism of then define
and define topological t-torsion in of (t-torsion part) of
i M't = lim (Coker t ), i>O
M = pre-image of the image
M under the natural mapping:
M .... M't) •
Then, in the short exact sequence (*) of the conclusion (1) of Corollary 1.2, notice that the first can be written equally well as Hn(C*)At/(topological t-torsion)
AAt-module in the sequence
Chapter 2
520
- i.e., the first
AAt-module of the short exact sequence (*)
of conclusion (1) of Corollary 1.2 is canonically isomorphic to the first
~t-module of the short exact sequence (*) of
the conclusion (1) of Theorem 1, taken modulo topological
t-
torsion. 2.
Notice also that the third
AAt-module in the short
exact sequence (*) of the conclusion (1) of Corollary 1.2 coincides with the third
AAt-module in the short exact sequence
(*) of conclusion (1) of Theorem 1.
Thus, the short exact
sequence (*) of conclusion (1) of Corollary 1.2 is a quotient (obtained by modding out by the topological t-torsion in Hn(C*)At
in the first
AAt-module, and its image in the second
AAt-module) of the corresponding short exact sequence,
(*) of
conclusion (1), of Theorem 1. 3.
Th e group
' 1 { prec~se , ' ' l im ti - t ors~on e 1 ements ln
i>O Hn+l(C*)
that are t-divisible}
1.2, is often zero.
in conclusion (2) of Corollary
E.g., if every t-divisible, precise t-
torsion element in
Hn+l(C*)
is infinitely t-divisible (which
is often the case.
See e.g., Proposition 3 of Chapter 1, and
Chapter 4 below), then by an induction on used in a
p~rtion
i >0
similar to that
of the proof of Proposition 3 of Chapter 1,
it is easy to see that every t-divisible,' precise ti-torsion element in gers
i > O.
Hn+l(C*)
is also infinitely t-divisible, all inte-
But, when that is the case, the inverse system of
which
liml is taken on the right side of equation (2) of Coroli~O lary 1.2; is an inverse system in which all the maps are epi-
morphisms.
Therefore, when this is the case( that is, when
every t-divisible, precise t-torsion element in
Hn+l(C*)
is
521
The Short Exact Sequence 1.8
infinitely t-divisible - a condition that often (although not always) holds -
) then both
, (2) of the AAt -mo d u l es 'ln equatlon
conclusions of Corollary 1.2 are zero.
(Thus, roughly speaking,
the two groups in equation (2) of Corollary 1.2 "more often are zero" than are the two groups in equation (2) of Theorem 1.
In
fact, more precisely, it is easy to show that the natural monomorphism of inverse systems:
({precise ti-torsion elements in
Hn+l(C*)
that are t-divisible})i>O +({precise ti-torsion ele-
ments in
Hn+l(C*)}), 1>0
induces a monomorphism after taking
liml (reason: the quotient inverse system is isomorphic to: i>O 'l (Tprecise t -torsion elements in Hn+l(C*)/(t-divisible elements)})i>O'
and this latter clearly has inverse limit zero.
Considering the exact sequence of six terms deduced from the short exact sequence of inverse systems by throwing through the
' ' 1 0 , ••• , 0 , ••• glves t he lim, l 1m, ito ito We record this latter parenthetical observa-
system of derived functors: desired result».
tion as a Corollary: Corollary 1.2.1. any fixed integer.
Under the hypotheses of Theorem 1, let
n
be
Then the two canonically isomorphic AAt_
modules appearing in equation (2) of the conclusions of Corollary 1.2 are canonically isomorphic to an AAt-submodule of either of the two canonically isomorphic
AAt-modules appearing
in equation (2) of the conclusions of Theorem I--the monomorphism:
liml({preciSe ti-torsion elements in i>O
Hn+l(C*)
t-divisible}) + liml({precise ti-torsion elements in ito being induced by the inclusion of inverse systems, ti-torsion elements in
Hn+l(C*)
({precise ti-torsion elements in
that are
Hn+l(C*)}) ({precise
that are t-divisible}) i>O + Hn+l(C*)}), O· 1>
522
Chapter 2 4.
We conclude Remark 8 with another corollary to Corol-
lary 1.2 to Theorem 1: Corollary 1.2.2.
Under the hypotheses of Theorem 1, the nota-
tions being as in Corollary 1.2, we have that for any fixed integer
n,
each of the equivalent conditions of Corollary 1.1
is equivalent to each one of the following two conditions: (1')
The natural map of
AAt-modules:
n [H (C*) I (t-torsion) ]A t ... lim [E~ (ti) ] i>O is an isomorphism. (3' ) i
~
uEE~(t)
Let
I,
such that
En(ti) 00
is
vEHn(C*)
u
be such that there exist l
= u
and such that the image of
all integers
ui '
n i ui E Eoo (t ),
i> 1-
such that the image of
v
ui +l
in
Then there exists (under the monomorphism in
the short exact sequence (*) of conclusion (1) of Corollary 1.2) in
E~(t)
Proof:
is
u.
Let condition (2') be identical to condition (2) of
corollary 1.1.
Then the proof of Corollary 1.1 (that conditions
(1), (2) and (3) of Corollary 1.1 are equivalent) shows equally well that conditions (I'), (2') and (3') above are equivalent (where, in the proof, the short exact sequence (*) of conclusian (1) of Corollary 1.2 takes the place of the short exact sequence (*) of conclusion (1) of Theorem 1). (3) and (1')-=(2')-=(3').
Thus (1)
~(2)~>
Since conditions (2) and (2') are
identical, the Corollary follows. Notes 1.
As noted above, the proof of Corollary 1.2.2 proceeds
by analogy to that of Corollary 1.1.
In particular , one also
The Short Exact Sequence 1.B
523
proves analogues of Lemma 1.1.1 and Lemma 1.1.2, namely Lemma 2.1.1. integer
n
Under the hypotheses of Corollary 1.2.2, for each and every integer
j
~
0,
we have the short exact
sequence 0->- (A/tjA)
(* , )
J
@
[Hn(C*)/(t-torsion)]
A
->- (A/tjA)
@
[I'm En (ti»)
A
Jo
00
->-(precise tj-torsion in
Hn + 1 (C*)
that is infinitely t-divisible) ->- O.
Lemma 2.1.2. every integer
Under the hypotheses of Corollary 1.2.2, for n,
and for every integer
j
~
0, the natural
mapping: (A/tjA)
@
A
[~im E~(ti)] ->-E~(tj) 1>0
is a monomorphism. The proofs of Lemmas 2.1.1 and 2.1.2 are exactly analogous to those of Lemmas 1.1.1 and 1.1.2, and need not be repeated. (And again, the proof of the equivalence of conditions (2') and (3')
of corollary 1. 2.2 makes use of Lemma 2.1. 2,
(in the same
way that the proof of Corollary 1.1 makes use of Lemma 1.1.2). Note 2.
The proof of Lemma 2.1.2, as the proof of Lemma 1.1.2,
makes use of the Five Lemma, and involves a commutative diagram in which the top row is the exact sequence (*,) of Lemma 2.1.1, J and the bottom row is the short exact sequence: (1)
j) 0->- (A/tjA) 0 [Hn(C*)/(t-torsion») ->-En(t co A
->- (precise tj-torsion in
Hn + 1 (C*)
that is t-divisible)
Chapter 2
524 +0,
established in Chapter 1, and is exactly as in Lemma 1.1.2. Notice also that, by the Five Lemma applied to that diagram, the mapping described in Lemma 2.1.2 will be an epimorphism (and therefore an isomorphism, since by the conclusion of Lemma 2.1.2 said mapping is always a monomorphism) iff the mapping from the rightmost group in the short exact sequence (*.) into the rightmost term of the short exact sequence (1) J
above is an epimorphism.
But clearly, that latter condition
will be so iff every precise tj-torsion element in that is t-divisible, is infinitely t-divisible. corollary 1.2.2.1. let
n
Hn+l{C*)
We now prove:
Under the hypotheses of Corollary 1.2.2,
be any fixed integer.
Then the following six conditions
are equivalent: (1)
For all integers [lim
j ,::,1,
the natural mappings:
E~(ti)l +E~(tj)
i>O are epimorphisms. (1' )
There exists an integer
j.::.l
such that the mapping:
is an epimorphism. (2)
For all integers
i,j
with
i.::.j.::.l,
the natural
mapping:
is an epimorphism. (2')
There exists an integer
j.:.l
such that for every
The Short Exact Sequence 1.8 integer
i.:. j
525
the natural mapping:
is an epimorphism. (3)
Every t-torsion element in
Hn+l(C*)
that is t-divis-
ible, is infinitely t-divisible. (4)
Every precise t-torsion element in
Hn+l(C*)
that
is t-divisible, is infinitely t-divisible. Proof:
(3) implies
fact, if we let
(4) is obvious.
Proof that
(4)~(3):
In
M=Hn+l(C*)/(infinitely t-divisible elements),
then throwing the short exact sequence: 0 .... (infinitely t-divisible elements in .... H
n+l
n H +l (C*))
(C*) +M .... O,
through the exact connected sequence of functors: 1
HO~ [T 1 (7 [T 1/T • it [T l,
),
letting
"t"--therefore the first of these func-
Ext [Tl (7 [Tl/T·7,1 [Tl, ) ,0, ••• ,0, ••• 7 (where every left A-module is regarded as a 7 [Tl-module by "T"
act as
tors, regarded as a functor on the category of left A-modules, is the functor:
N~>
(precise t-torsion in
of these functors is the functor:
N),
N~>N/tN),
and the second we obtain an
exact sequence of six terms, a portion of which implies that every precise t-torsion element in precise t-torsion element in (4)~(3),
that
~.
M in
Let
A
M
is the image of some
Hn+l(C*).
Therefore, to prove
it suffices to prove the following be a ring, let
t
be an element of
A
and let
be a left A-module such that every precise t-torsion element M
that is t-divisible is zero.
Then
M
has no non-zero
Chapter 2
526
t-divisible, t-torsion elements.
(Proof of Lemma:
be at-divisible t-torsion element. fact, since J. _> 1
If
Lemma.
To show that
t
j = 1,
j
By induction on
• u = O.
t-divisible.
By inductive assumption,
and
of the Lemma,
u
v
= tu.
Then let
= v = 0,
Since
Then
is t-divisible.
u == 0,
In
we show that
j.:::. 1,
t
j
• v
to prove it
and that
=0
and
v == O.
u
is
v
is
But then
Therefore by the hypotheses
completing the induction and therefore
the proof of the Lemma.) Therefore
j,
t j +l • u = 0
I.e., suppose that
t-divisible.
tu
u = O.
then this follows from the hypotheses of the
Suppose the assertion is true for
j + 1.
u EM
is a t-torsion element, there exists an integer
such that
u = O.
for
u
Let
This completesthe proof that
(4)~(3).
(3)~(4).
(3)
<~
(4), it follows that, for each integer
j
~
1,
that (3) and (4) are both equivalent to the condition. (4 ) j
Every precise tj-torsion element in
Hn+l(C*)
that
is t-divisible, is infinitely t-divisible. But by the observation immediately preceding the statement of Corollary 1.2.2.1, the condition (4.) is equivalent to the J
mapping of Lemma 2.1.2 being an epimorphism.
And this latter
condition is clearly equivalent to (lj)
The natural mapping: [ 1'*"m En (t i) 1 + En (t j ) i>O 00
00
is an epimorphism. Thus, for every integer Since also
(4j)~(4)~(3),
tion (1.) is independent of J
j
~
1,
we have that
it follows that, for j.
(1.)-=(4.).
J
j '::1,
J
condi-
Therefore conditions (1) and
The Short Exact Sequence 1.8
527
and (1') of the Corollary, and condition (1.), for any fixed J
~
integer
j
1,
are all equivalent.
Therefore (1)
¢=>(4).
It is obvious that (1)<=>(2) and (1')
~(l') ~(3)
<~(2').
proves Corollary 1.2.2.1. Remark 9.
This Q.E.D.
Under the hypotheses of Example 1 of Remark 3; or
of Theorem l' of Remark 3; or of Theorem 2' of Remark 4; or of Theorem 2 of Remark 5; or of the Theorem of Remark 6; in lieu of the hypotheses of Theorem 1, we obtain a Corollary exactly analogo us to Corollary 1.2 of Remark 8 - with observations analogous (and in no way weaker) to Note 1 of Remark 8, to Note 2 of Remark 8, to Note 3 of Remark 8, incl. Cor. 1.2.1 of Note 3 of Remark 8, and to Note 4 of Remark 8, including Corollary 1.1.2 of Note 4 to Remark 8, all holding under these modified hypotheses. (Of course, under the hypotheses of Theorem 2' of Remark 4, for each integer
i >1
the Bockstein abutment
n E 'l',
(and indeed the whole generalized Bockstein spectral sequence n
(Er(t
i
n
),dr)nE~)
is taken to be that corresponding to the long
r>O exact cohomology sequence displayed in the first paragraph of the proof of Theorem 2' of Remark 4--i.e., the long exact sequence of cohomology of the short exact sequence of cochain complexes: O+C*+Dt+C*(+l) +0,
where 4).
D~ 1
is defined in the statement of Theorem 2' of Remark
(And under the hypotheses of Theorem 2 of Remark 5, for
each integer
i
~
0,
the Bockstein abutments
i ) En(t 00
deed the whole generalized Bockstein spectral sequence
(and in-
528
Chapter 2
(E~(ti),d~)n~)
is taken to be that defined by the cochain
r>O
complex of A-modules the center of
A
C*
t i EA
and the element
and is a non-zero divisor in
(that is in
A),
as defined,
in any of three different ways, in the footnote to Remark 4 fol(And, of course, under the
lowing Theorem 2 of Chapter 1).
hypotheses of the Theorem in Remark 6, for each non-negative integer
i,
the Bockstein abutments
i) En(t 00
(and indeed the
whole generalized Bockstein spectral sequence
n
i
n
(Er(t ) ,d r )nE7) r>O
is taken to be that corresponding to the long exact sequence (I' )
(the labeling of the sequence being as in proof of the Theorem of Remark 6)--recall that this long exact sequence is obtained from the long exact sequence (Ii)'
(as labeled in the proof of
the Theorem of Remark 6) by making the identifications (2)
(as
labeled in the proof of the 'rheorem of Remark 6); and that the long exact sequence (Ii) of the proof of the Theorem of Remark 6 is the long exact sequence obtained by applying the exact connected sequence of functors
Tn,
n E :l ,
to the short exact
sequence
in the category
C,
all integers
i >0
(again, the labeling
being as in the proof of the Theorem of Remark 6». under these various
Similarly,
sets of hypotheses, the analogues of Lemmas
2.1.1 and 2.1.2 also hold.
And under these modified sets of
hypotheses, the analogue of Corollary 1.2.2.1 also holds-with
The Short Exact Sequence 1.8
529
the exception that, in the abelian-category theoretic cases (that is, in Example 1 and Theorem I' of Remark 3; Theorem 2' of Remark 4; or in the Theorem of Remark 6) one should delete the conditions (2) and (2') in the statement of Corollary 1.2.2.1, unless one also assumes the Axiom (P.2), see Introduction, Chapter 1, section 7 (in the category
A when under the hypo-
theses of Theorem I' or Theorem 2'; and in the category
6
when
under the hypotheses of Example 1 of Remark 3 or of the Theorem of Remark 6).
This Page Intentionally Left Blank
CHAPTER 3 COHOMOLOGY OF AN INVERSE LIMIT OF COCHAIN COMPLEXES
In this chapter we recall a classical exact sequence, corning from a well-known spectral sequence.
The material of
this brief chapter is indeed very well known (all that is used is among the simplest, best-known cohomological spectral sequences), and Chapter
is included merely for internal com-
3
pleteness of this book.
In consequence, proofs are not given
in extreme details (and theorems are labeled as propositions). Proposition 1.
Let
(C~,a~.) . . 0 1. 1. J 1., J'::'
be an inverse system indexed
by the non-negative integers of cochain complexes (indexed by all the integers) of left A-modules, where identity. (I)
A
is a ring with
Then there are induced A sequence , integer
n
An,
E; J! ,
n E J! ,
of A-modules, and for each
a short exact sequence
(2)
and also there is induced a long exact sequence (extending to
+ '" on the right):
on the left, and
{3}
n-l ~> Hn (lim c~) i~O
.... An .... Hn - l (l1ml
i>O
1.
n
n
H + l (lim Cp .... A + l ....... i~O
531
n
c~) J!..., 1.
532
Chapter 3
Note:
The statement and proof of this Proposition go through
A such that denumerable direct products
to any abelian category
of objects exist; and such that the direct product of denumerably many epimorphisms is an epimorphism (i.e., such that the functor "denumerable direct product" preserves epimorphisms). Proof:
We define a double complex of left A-modules
(O p,q , dP,q (1,0)' dP,q (0,1) ) p,qE.?· C~ ....
C~
J]
1
i>O
1
F"lrs, t f or eac h ln " t egerI n, t e
be the map such that
all integers
i
~
0,
where
C~ .... C~
1\":
J
1
is the i I th projec-
1
and where
tion, all non-negative integers is the map in the inverse system Then, define on,O = On, 1 =
c~,
J]
all integers
n,
i>O on,m = 0,
all integers
d70~l): on,O .... on,1 d70~1) = 0, n
the map
all integers
m=O J]
i>O
d~: 1
such that
to be the map
m,. 0,
and for
n,m
1,
or J]
i>O
C~ .... 1
n.
define J]
i>O
c~+l, 1
d7i~ 0) = 0, Then
i,j,
all integers
dP,q ) (O p,q , dP,q (1,0)' (0,1)
Define
and (necessarily) define
Finally, for each integer
dn,m . on,m on+l,m (1,0) . " .... where
n'th coboundary in the cochain complex all non-negative integers
m,. 0,1.
d~: C~ .... C~+l 1
Ci,
1
1
to be is the
all integers
n,
and (necessarily) define n,m
such that
m,. 0,1.
is a (whole plane) double complex
Inverse Limit of Cochain Complexes of left A-modules such that
op,q
=0
unless
q
533
=0
or
1.
Therefore we have the two spectral sequences of this double complex, both abutting at the total cohomology of the double complex (4)
Let
0**.
An = Hn (0**),
the n'th total cohomology group, all integers
n.
Then the two
spectral sequences are respectively of the form: (5)
EP,q 2
=
HP(limq (C*
*)
'>0 1" a 1J" ,1,J_
+' i>O
)~ An
'
and (6)
(of course with, in general, different filtrations on
An).
The
EP,q-term of the spectral sequence (5) is confined to the hori2
zontal strip
q
=0
or
I,
and the
EP,q-term of the spectral 2
sequence (6) is confined to the vertical strip
p
=0
or
1.
Therefore, the spectral sequence (5) simplifies to the long exact sequence: n C"!,)....Q......,,
(5' )
1
where the map labeled boundary
n "d "
in the sequence (5') is the co-
d~-l,l: E~-l,l -.. E~+l, 0
in the
E~' q-term of the spec-
tral sequence (5), and where the other maps in the long exact sequence (5') are the edge homomorphisms in the spectral sequence (5).
Similarly, the spectral sequence (6) simplifies to
the short exact sequences
Chapter 3
534
(6' )
all integers
n.
Equations (4),
(5') and (6') imply the Propo-
sition. Remark 1.
Notice that, if
(C~,U~
'>0
is an inverse system
of cochain complexes as in Proposition I,
(or as in the Note to
Proposition I), then
1
,),
1J 1, J_
An=An[(Ci'Uij)i,j~Ol
the proof of Proposition 1 for each integer
as constructed in n
depends only on
the inverse system:
h
(a ij )n-2::,h < n+l
i, j
':.0
- i.e., only the portion of the cochain complexes, from
n-2 n+l n-2 n ' Ci the coboundaries: d i , ... ,d , and the maps: ' ... 'C i i n-2 n+l n ui,i-l,···,ui,i-l are required to define A [(ct,utj)i,j~Ol, for each integer Remark 2.
n.
Notice that the groups
structed in the proof of Proposition I, all integers
conn, form an
exact connected sequence of functors from the abelian category having for objects all inverse systems (indexed by the non-negative integers) of cochain complexes (indexed by all the integers) of left A-modules (or, under the more general hypotheses of the
Inverse Limit of Cochain Complexes
535
Note to the Proposition, of objects in the abelian category
A
obeying the hypotheses of the Note), into the category of left A-modules (or into Remark 3.
A).
If we restrict Proposition 1 to inverse systems (in-
dexed by the non-negative integers) of non-negatively indexed cochain complexes of left A-modules, then it is easy to see that the restriction of the exact connected sequence of functors An, n E 'l',
to this subcategory, for
n >
a
form a system of de-
rived functors of the functor: AO[(C'!",CI.'!',),
lim HO(C'!'). And, for such a special inverse i>O ~ system (of non-negatIvely indexed cochain complexes), ~
(C~, CI.~ ~
~J
,),
~J
'>OJ
~,J_
'>0'
=
it is easy to interpret the spectral sequences
~,J_
(5) and (6) of Proposition 1 as being the spectral sequences of the composite functors: O (H )
0
(lim), i>O
and
respectively.
(This observation even makes sense at the abelian
category-theoretic level,
i.e., under the hypotheses of the
Note to Proposition 1, with no additional hypotheses, once one observes that all the indicated derived functors exist in the reasonable sense, and that the spectral sequences of the indicated composite functors also exist). Corollary 1.1.
Let
(C'!',CI.'!",) , 1
~J
'>0
~,J_
be an inverse system (indexed
by the non-negative integers) of cochain complexes of A-modules (indexed by all the integers) and let
C* = lim C!. i>O
Suppose
Chapter 3
536
that the natural mappings: Cn
-r
all integers
C~
are epimorphisms, all integers
n.
Then there are induced short exact sequences:
~
0+ Ij,m l [H n - l (C"«) 1 ~
i>O
all integers Note:
+
Hn(C*)
+
i ~ 0,
Ij,m[Hn(C~) 1 + 0,
i>O
~
n.
The hypothesis in this Corollary "of A-modules", can be
replaced by:
"of objects and maps in the abelian category
A,
A is any abelian category such that denumerable direct
where
products exist and such that the denumerable direct product of epimorphisms is an epimorphism". Proof:
The proof is the same.
The hypotheses of Proposition 1 are obeyed.
have (1) a sequence
n E ;r ,
Hence we
of A-modules, and the exact se-
quences (2) and(3) of the conclusions of Proposition 1. hypothesis, for each integer epimorphisms, all integers all integers Ij,m
i>O
n, l
n, i :> O.
the mappings: Therefore
C
n
+
i>O
are
Cr: ~
liml[C~l ~
But by
=
0,
so that
C"« = O. ~
But then the long exact sequence (3) of Proposition 1 becomes a sequence of isomorphisms: (3' )
substituting these isomorphisms into the short exact sequences (2) gives the conclusions of Corollary 1.1. Remark:
In the short exact sequence, for each integer
the conclusion of Corollary 1.1, the epimorphism:
n,
in
Inverse Limit of Cochain Complexes Hn(C*) -+ lim[Hn(C~)]
ito
537
is induced by the natural mappings:
1
Hn(C*) -+ Hn (C~) ,
all integers
1
i > 0
Hn(natural map:
means, explicitly,
(where "natural mapping" C*-+C!».
This observa-
tion follows easily by tracing the construction. Corollary 1.2.
Let
C*
be a cochain complex, indexed by all
the integers, of left A-modules where be a left ideal in
A
A
is a ring, and let
such that the left A-module
cally complete, all integers
n.
n C
I
is I-adi-
Then there are induced short
exact sequences O-+lj,ml[Hn-l(C*/IiC*)]-+Hn(C*) -+~!m[Hn(C*/Iic*)]-+o,
i>O
1>0
all integers Proof: n C
n.
C~=C*/Iic*, 1
Define
all integers
i > O.
Then since
is I-adically complete as left A-module, all integers
n,
we have a canonical isomorphism of cochain complexes of left A-modules hold.
C* "" lim
i>O
C~;
1
and the rypotheses of Corollary 1.1
Therefore-we have the conclusion of Corollary 1.1, which
implies the conclusion of Corollary 1.2.
Q.E.D.
Remark:
Another special case of Corollary 1.1 is as follows.
Let
be a
C*
(~-indexed)
abelian category to Proposition 1. cochain complex
A, Let C*.
cochain complex of objects in the
where
A obeys the hypotheses of the Note
t*:C* -+C*
be any endomorphism of the
Then we obtain short exact sequences:
0-+ liml [H n - l (C*/ (t*) i c *) 1 -+ Hn [(C*)At*] i.::O n -+ lim [H (C*/ (t*) i c *)] -+ 0,
i.::O where
"C*/(t*)ic *" = "Cokernel of the i'th interate of
t*",
538
Chapter 3
"C*l\t*" = "lim c*/(t*i)c*". (Proof: Let c~=c*/(t*)ic*. 1 i>O n Then the natural map: C .... C~ is an epimorphism, therefore so and
1
is the natural map:
(Cn)l\t* .... C~ 1
Therefore Corollary 1.1 applies).
all integers
i, n,
i> O.
CHAPTER 4 COHOMOLOGY OF COCHAIN COMPLEXES OF t-ADICALLY COMPLETE LEFT A-MODULES
In this chapter, we discuss some consequences of the exact sequences (I.8) of (P.P.WCJ,
(i.e. of Theorems 1 and 2 of Chapter
2), and of Corollary 1.1 of Chapter 3. Theorem 1.
Let
element of
A.
A Let
be a ring with identity and let C*
t) :C n
(multiplication by tegers
be an
be a cochain complex (indexed by all
the integers) of left A-modules, such that n (1) C is t-adically complete, all integers (2)
t
-+
Cn
n,
and
is injective, all in-
n.
Then (1)
For every integer
n,
Hn(C*)/(t-divisible elements)
is t-adically complete. (2)
For every integer
n,
Also, Hn(C*)
has no
non-zero in-
finitely t-divisible, t-torsion elements. every integer
n,
we have the canonical isomorphism
of abelian groups (or of A-modules if center of (3)
Also, for
t
is in the
A):
Hn(C*)/(t-divisible elements) ~ Hn(c*)At~ lim(Hn(C*/tic*»). Also, for every integer n, there i>O are induced canonical isomorphisms of abelian groups
(4)
(or of A-modules, if
t
(t-divisible part of
n H (C*) ) ~ 539
is in the center of
A):
Chapter 4
540
~ liml[precise ti-torsion in itO
Hn(C*)]
~ limlHn-l (c*/tic*). i>O Remark:
We will see later (Theorem l' below), that under the
hypotheses of Theorem 1, a stronger conclusion than (2) holds; namely, (2')
For every integer
n,
Hn(C*)
has no non-zero in-
finitely t-divisible elements. An amusing, and useful, corollary of Theorem 1 is Lemma 1.1.1.
Let
A
element of the ring MAt
be a ring with identity and let A.
Let
be the completion of
Let
?l. [T]
-+
A
identity that sends
M
for the t-adic topology.
~t
replacing
"A" by
If
M
has no non-zero t-torsion.
be the unique homomorphism of rings with T
ring in one variable
be an
M be a left A-module and let
has no non-zero t-torsion, then Proof.
t
into T
t,
where
over the ring and
"?l.[T]"
"T"
prove the Lemma in the case that
by
?l.[T]
is the polynomial
of integers.
?l.
"tn,
A =?l. [T],
t
Then
it suffices to
= T.
We assume
this for the rest of the proof. Let
P*
be a free resolution of the
?l. [T]-module
M.
Then define
. IP
C~ =
i
. ,
-~
i > 0.
0,
Then c
n
C*
2. 0,
is a cochain complex (that is non-positive) such that
is a free
(1)
?l. [T]-module, all integers
H" (C<) - /
M,
n = 0,
0,
n
i
0.
n,
and such that
Cohomology of Cochain Complexes Then
c
M
(=
c
M
T),
541
being the T-adic completion of a free n E J7..
J7. [Tj-module, is with no non-zero T-torsion, all integers
Therefore the cochain complex of the hypotheses of Theorem 1. of Theorem 1,
z[Tj-modules:
limlH-l(C*AT/Tic*AT).
ito
A
obeys all
In particular, by conclusion (4)
(T-divisible part of
(2)
C*
But (3)
HO(C*AT)) ~
(C*AT /TiC*AT) ~ C*/TiC*.
A por-
tlon of the long exact sequence of cohomology of the short exact sequence of cochain complexes of i . 0 ... C*~ C* ... C*/T~C* ...
z[Tj-modules
°
is the exact sequence: i
(4)
••• ..!.....;.H- l (C*) ... H- l
But by equation (1), Ti: HO (C*) ... HO (C*)
.
i
-1
(C*/T~C* )~HO (C*~HO (C*)-
HO(C*) =M,
so that the endomorphism
is injective, since by hypothesis
non-zero T-torsion; and also by equation (1),
H-
l
M
has no
(C*) = 0.
Therefore from equation (4) we deduce that (4')
H- l (C*/TiC*) = 0,
all integers
i > 0.
substituting this into equations (2) and (3) yields (5)
(T-divisible part of
HO (C*AT)) = 0.
Equation (5) and conclusion (3) of Theorem 1 (for the cochain complex
(C*)AT
and the integer
n = 0)
imply that
substituting equation (3) into this latter result yields (6)
HO (C*AT)
~ lim HO (C*/TiC*). i>O
542
Chapter 4
But, from the cohomology sequence of the short exact sequence of cochain complexes:
°
i -+
.
c*....!...- C*
-+
C* ITlC*
-+
0
and from equation (1) and the fact that
M
has no non-zero T-
torsion we deduce that i
(7)
. MIT M, n H (C* ITlC*) = 0,
j
all integers
n,i
with
i > 0.
n=O n
~
0,
Substituting equation (7) into
equation (6) yields (8 )
A portion of the cohomology sequence of the short exact sequence of cochain complexes:
is the exact sequence (9)
~
But equation (3), and equation (4') with
i=l,
Substituting into equation (9), it follows that no non-zero T-torsion. non-zero T-torsion. Corollary 1.1. i ) r>O En(t r I _
'
Therefore by equation (8)
imply that
HO(C*AT)
~T
Q.E.D.
Under the hypotheses of Theorem 1, let
i) En(t 00
...
be the generalized Bockstein spec-
has
has no
Cohomology of Cochain Complexes
543
tral sequence, as defined in Chapter 1, corresponding to the cochain complex t
i
":
C*
->-
C*.
C*
and the endomorphism "multiplication by
Then for every integer
n,
there is induced a
canonical isomorphism of abelian groups (or of A-modules if is in the center of
(1)
t
A):
Hn(C*)/(topological t-torsion)~ lim E~(ti),
i>O and an isomorphism: (2)
that is t-divisible in
Hn+l(C*)}).
(In equation (1) of Corollary 1.1, the phrase "topological ttorsion" means: left A-module Note:
Hn(C*)
of the subgroup
{t-torsion elements}".)
Theorem 1 and Corollary 1.1 both generalize to abelian
categories. "Let
"the closure for the t-adic topology of the
Namely, replace the first sentence of Theorem 1 by
A be an abelian category such that denumerable direct
products of objects exist, and such that the denumerable direct product of epimorphisms is an epimorphism (i.e., and such that the functor "denumerable direct product" preserves epimorphisms). And, in the second sentence of Theorem 1, replace the phrase "of left A-modules" by "of objects of endomorphism of the cochain complex
A,
and let C*".
t* :C*
->-
C*
be an
The rest of Theorem 1
and Corollary 1.1 then remain the same, with
"to
changing to
"t*", and with the obvious understanding (as discussed in Chapter 2) of what "t*-adically complete", or "t*-divisible" means. (E.g. ,
"Cn
is t*-adically complete" means that the natural map
544
Chapter 4
Cn-+lim [Coker«t*)i:cn-+cn)] i"t"O Proof of Theorem 1.
is an isomorphism).
Since (multiplication by
injective, all integers
n n C -+ C
t):
is
n, the hypotheses for the exact sequence
(1.8) of [ERWCJ, i.e., of Theorem 1 of Chapter 2 hold, and therefore the conclusions of Theorem 1 of Chapter 2, hold: For each integer (1)
n,
we have a short exact sequence
S; lim [H n (C * / tiC *) ] -+ i"t"O n lim (precise ti-torsion in H + l (C*) ) -+ 0,
o -+ Hn (C * ) At i>O
and for each integer
n
we have an isomorphism
(2)
cn
On the other hand, since by hypothesis plete, all integers integer (3)
n
n,
is t-adically com-
by Corollary 1.1 of Chapter 3 for each
we have the short exact sequence
O-+lj:ml[Hn-l(c*/tic*)] .... Hn(C*) f}li m [Hn(C*/tic*)] .... O. i>O i>O
As we have observed in Chapter 2, respectively: monomorphism
a
(respectively:
short exact sequence (1)
the epimorphism
(respectively:
Chapter 3, the
S)
in the
in the short exact se-
quence (3)) is induced by the natural mappings:
But since the group natural map: n H (C*)
~ lim [H n (C* /tic*) ] i>O
can be factored:
is t-adically complete, the
545
Cohomology of Cochain Complexes
Hn(C*) .... Hn(C*)At ~ Ij,m[Hn(c*/tic*) J.
(4)
i>O
8
Since
is an epimorphism (by exactness of the sequence (3»,
it follows from the factorization
(4) that
But from the exact sequence (1),
a
fore the natural map
a
a
is an epimorphism.
is a monomorphism.
There-
is an isomorphism:
( 5)
substituting the isomorphism (5) into the short exact sequence n l lim (precise ti-torsion in H + (C*» = 0, or i~O equivalently, that- Hn+l(C*) has no non-zero infinitely t-divi-
(1) we see that
sible, t-torsion.
n
being an arbitrary integer, this proves
conclusion (2) of the Theorem. Equation (3)
implies that the composite map
8
of the maps
in (4), is an epimorphism, and equation (5) that the map (4)
is an isomorphism.
a
in
Therefore, it follows that the first
mapping in (4), the natural mapping:
It is equivalent to say that Hn(C*)/(t-divisible elements) is t-adically complete. Theorem.
That proves conclusion (1) of the
Next, note that conclusion (1) of the Theorem and
equation (5) above imply conclusion (3) of the Theorem. The short exact sequence (3) the map that
(in which the epimorphism is
e), the factorization (4) and the fact, equation (5), a is an isomorphism imply that the kernel of the natural
Chapter 4
546 mapping: y:Hn{C*) -+Hn{C*)At
is
canonically isomorphic to
liml[Hn-l{C*/tiC*)] . i>O But clearly the kernel of
y
(the natural mapping into the
completion) is {t-divisible elements in
Hn{C*)}.
Thus, we
have established the canonical isomorphism (6)
Hn (C*) ) :';' l~ml [H n - l (C* /tic*) ] , i> 0
(t-divisible part of
all integers
n.
Equation (2), with n-l replacing
n,
and equation (6) above
imply the conclusion (4) of Theorem 1. Proof of Corollary 1.1.
Q.E.D.
By Corollary 1.2 in the terminal Re-
marks (Remark 8) of Chapter 2, for each integer
n
we have the
short exact sequence (1)
0-+ Hn(c*)At/{topological t-torsion) -+llm[En{t i )]-+ i>O n l lim{precise ti-torsion in H + (C*» -+ 0,
i>O and for each integer (2)
n,
we have a canonical isomorphism:
lim En {til ~ liml ({precise ti-torsion in i>O ito Hn+l(C*)
that is t-divisible in
Hn+l{C*)}).
Equation (2) is conclusion (2) of the Corollary. (2)of the Theorem,
Hn+l{C*)
By conclusion
has no infinitely t-divisible,
t-torsion elements - equivalently, lim (precise ti-torsion in i>O
Hn + l (C*»
=
o.
Cohomology of Cochain Complexes
547
substituting this last equation into the short exact sequence (1) gives conclusion (1) of this Corollary. Proposition 2.
Q.E.D.
Under the hypotheses of Theorem 1, let
any fixed integer.
n
be
Then the following conditions are equiva-
lent:
(1)
Hn(C*)
is t-adically complete.
(2)
Hn(C*)
has no non-zero t-divisible elements.
(3)
The natural mapping:
is an isomorphism of abelian groups, ter of (4)
A,
(a)
(b)
t
is in the cen-
of left A-modules). If u
and
(or, if
ufHn(C*),
t·u=O,
and
u
ist-divisible,then
is infinitely t-divisible. n u f H (C*)
If
and
t
i
u'l
0,
all integers
i,
then
u
is not t-divisible.
(5) (6)
, i , , , 1( I 1m preC1se t -tors10n 1n
ito
limlHn-l (C*/tiC*) = O. i>O
Corollary 2.1.
Under the hypotheses of Theorem 1, let
n
be an
integer such that the six equivalent conditions of Proposition 2 above hold.
Then, the notations being as in Corollary 1.1, we
have that (1)
lir'llE~(ti) = O. i>O
Proof of Proposition 2.
(1)1=* (2)
follows from conclusion (1) of
Chapter 4
548
Theorem 1.
Conclusion (2) of Theorem 1 is that
Hn(C*)
non-zero infinitely t-divisible t-torsion elements.
has no
Therefore
condition (4a) of this Proposition is equivalent to saying that Hn(C*)
has no non-zero t-divisible, precise t-torsion elements,
which is in turn equivalent to asserting that
Hn(C*)
has no
non-zero, t-divisible elements that are t-torsion elements. condition (4b) says that that are not
Hn(C*)
But
has no t-divisible elements
t-torsion elements.
Therefore (because of conclu-
sion (2) of Theorem 1), condition
(4)<~
condition (2).
The iso-
morphism of the first and third groups in conclusion (3) of Theorem 1, implies that condition (2) of this Proposition is equivalent to condition (3) of this Proposition. (l~ (2)~3~(4).
Therefore
Finally, conclusion (4) of Theorem 1 implies
the equivalence of conditions (2),
(5) and (6) of this Proposi-
tion.
Q.E.D.
Proof of Corollary 2.1.
Consider (for the fixed integer
n) the
short exact sequence of inverse systems, indexed by the nonnegative integers, of abelian groups: (1)
0 ->- ({precise ti-torsion in
Hn(C*)
that is t-divisible in
Hn(C*)})i>O ->- ({precise ti-torsion in ->-
Hn(C*)})i~O
({preCiSe t~-torsion in Hn(C*)}) {precise tl-torsion in Hn(C*) that is t-divisible in Hn(C*)} i>O
->- 0, (where the maps, e.g. {precise ti+l-torsion in {precise ti-torsion in
Hn(C*)}
Hn(C*)}->-
in the middle inverse system,
Cohomology of Cochain Complexes is induced by "multiplication by Let
(ui)i>O
549
t", all integers
~
i
0).
be an element of the inverse limit of the
third of the inverse systems in the short exact sequence of inverse systems (1). represent
u ' i
we have that
Let
u. E {precise ti-torsion in 1.
all integers
Then for all integers
i, j
~
0,
j
• u.+. -u.) E{t-divisible elements in Hn+l(C*)}. 1. J 1. j In particular, we can write t • u . . - u . = tjv. for some ele1.+J '1. J
n l v. E H + (C*).
ment u. E t 1.
(t
i.
Hn(C*)}
j
J • Hn(C*),
sible in
But then
all integers
Hn(C*).
But then (Ui)i>O
u. = t j • (u. +' - v . ), so tha t 1.
U = 0, i
J
1.J
j ~ O.
Therefore
u.
1.
all integers
is t-divii> O.
There-
being an arbitrary element of the
inverse limit of the third inverse system in the short exact sequence (1), it follows that the inverse limit of that inverse system is zero:
(2)
lim
{precise
itO
{precise ti-torsion in that is t-divisible in
Therefore, throwing the short exact sequence (1) through the system of derived functors
lj,m, lj,ml, i>O i>O
a portion of the re-
suIting exact sequence of six terms is the short exact sequence
(3)
1 Grecise ti-torsion in~ I (precise Hn (C*) that is t-divi- ->- lj,m sion in i~O ible in Hn(C*) i~O
o ->-lj,m
->-
liml~precise i>O -
)-+
n ti-torsion in H (C*) } {precise ti-torsion in HnAC*) that is t-divisible in H (C*)}
O.
But by condition (5) of Proposition 1 we know that the middle term in the short exact sequence (3) is zero.
Therefore so is
Chapter 4
550
the first term in this sequence.
But this is the second group
in the isomorphism in conclusion (2) of Corollary 1.1.
There-
fore the first group in conclusion (2) of Corollary 1.1 is zero, i.e., we have verified conclusion (1) of Corollary 2.1. Remarks:
1.
The full strength of the hypotheses of Theorem 1
were not used in the proof of Corollary 1.2 above.
Thus, the
proof of Corollary 1.2 above can be used to show that: Proposition 3.
("Corollary
1.2.1, Chapter
2." )
Under the
hypotheses of Corollary 1.2 in the terminal Remarks (Remark 8) of Chapter
2, for any fixed integer
n, if
then
l!mlE~(ti)
=
o.
i>O Proof:
We prove the assertion for the integer
n - 1
instead of
n. The proof of Corollary 2.1 of this chapter establishes the short exact sequence (3) of the proof of Corollary 2.1 above, under the hypotheses of Corollary 1.2 of Chapter the isomorphism (2) of Theorem 1 of Chapter phism (2) of Corollary 1.2 of Chapter of "Corollary 1.2.1, Chapter
2.
Then use
2, and the isomor-
2, to complete the proof
2", for the fixed integer
n-l.
(This observation could have, and possibly should have, been included in a Remark to Corollary 1.2 of Chapter "Corollary 1.2.1, Chapter
2.
Thus
2" generalizes to all of the many
situations (including abelian categories, restricted cochain complexes in abelian categories, etc.) under which Corollary 1.2
551
Cohomology of Cochain Complexes of Chapter Chapter
2 holds, as observed in the terminal Remarks of
2.
Also, the short exact sequence (3) of the proof of
Corollary 2.1 above also holds in these many cases}. Remark 2.
Let
A
be a ring with identity and let
M be a left A-module.
Then for each integer
t
i >0
E;
A.
Let
we have the
short exact sequence: 0-+
{precise ti-torsion in
is the inclusion and
where tion by
tilt.
For each integer
Pj. M T~i
M} -+
i
t M+O,
T T
is induced by "multiplica(1 i + 1) maps
i ;: 0, the sequence
where h + l , k i + l , E: + l ' i i tit, h + is the restriction of i l £i+l is the inclusion. Therefore
into the sequence (li)' by mappings
k + l is "multiplication by i "multiplication by t", and
we have the short exact sequence of inverse systems, indexed by the non-negative integers, of abelian groups (or of left A-modules, if (1)
t
is in the center of
A):
0 + ({precise ti-torsion in M}) i>O + ( . . .
(tiM) i>O
$
M
t
M
t
M)
-+
O.
-+
Throwing through the exact connected sequence of functors (in fact, system of derived fUnctors) lim, 11ml,
i>O
gives a short exact
i>O
sequence of six terms from which we deduce the following Theorem 4. A-module.
Let
A
be a ring, let
Then there is
tEA
and let
(ll
be a left
induced an exact sequence of five terms
of abelian groups (of or left A-modules, if of
M
t
is in the center
A): 0
-+
{infinitely t-divisible elements in
elements in
M} -+ {t-divisible
M}-+[l1ml(precise ti-torsion in
i>O
M)]-+
Chapter 4
552
[lj,m i>O
l
(. ..
(The term Proof:
.t
M
.t
M
"rI'IM"
.t
M) 1
-+
M" 1M -+ O.
is shorthand for
"rI'l (image of
M)".)
Consider the exact sequence of six terms alluded to in
Remark 2 above. lJ,m(tiM) i>O
= n
The third term in this sequence is
tiM
= it-divisible
elements in
M},
that is, the
i>O
the second term in the sequence (1) claimed in the Theorem. second term in the exact sequence of six lim( ... ~ M i>O
.t
M
.t
lim(tiM)
group in
terms is
M), a group that is zero iff
finitely t-divisible elements. is
The
M
has no in-
Clearly, the image of this
{infinitely t-divisible elements}. There-
itO fore,
(if we start with the image of the second term in the
third, of the exact sequence of six terms, then) the exact sequence of six terms determines an exact sequence of five terms, the first four terms of which are the first four terms of the sequence (1).
To co~plete the proof of the Theorem, it is neces-
sary and sufficient to establish a canonical isomorphism:
But in fact, this latter follows from the following elementary general observation, proved in Intro. Chap. 2, sec. 6, Cor. 7.1. Lemma:
If
(Ni,aij)ij~O
is any inverse system of abelian groups
indexed by the non-negative integers such that morphism, all integers
i,j
with
N
~ij
is a mono-
then there is in-
duced an isomorphism ompletion of
C
NO
by the subgroups
N.R<
1.
for the topology given\
N., . 1. (1.mage of
i >0 NO)
)
Cohomology of Cochain Complexes Proof:
553
Consider the short exact sequence of inverse systems in-
dexed by the non-negative integers: 0 ... (N, , a., ,), ~
where
NO
~J
, 0'" NO'" (NO/N, ), 0'" 0,
~,J~
~
~~
denotes the constant inverse system
through the exact connected sequence of functors
NO.
Throwing
' l'tm, 1 l l.m, i>O i>O
and considering the second, third and fourth terms in the resulting exact sequence of six terms, and the fact that the fifth term is Remark 1.
limlN = 0, it"O o
we obtain the Lemma.
By Theorem 4, if
element and if
M
A
is any ring, if
tEA
is any
is any left A-module, then there is induced
a natural mapping of abelian groups (or of left A-modules if is in the center of (2)
t
A): M} ... [lim l (precise ti-torsion in M)] • it"O
{t-divisible elements in
Now suppose that the hypotheses of Theorem 1 hold, and let M=Hn(C*)
for some integer
n.
Then, by conclusion (3) of
Theorem 1, there is induced a natural isomorphism of abelian groups (or of left A-modules if (3)
{t-divisible elements in
t
is in the center of
A):
M}~ [11ml(precise ti-torsion in M)]. i>O
If we study the proofs of Theorems 1 and 4, we see readily that, under the hypotheses of Theorem 1, the homomorphisms (2) and (3) coincide.
In particular, under the hypotheses of Theorem 1, the
homomorphism (2) is an isomorphism.
Substituting into the
exact sequence (1) of Theorem 4, we obtain: Theorem 1'.
Under the hypotheses of Theorem 1, the following
554
Chapter 4
assertion (which is stronger than conclusion (2) of Theorem 1) holds: (2')
Hn(C*)
has no non-zero infinitely t-divisible ele-
ments. A corollary to Theorem l' is Proposition 2'. tion 2.
Suppose that the hypotheses are as in Propos i-
Then the following condition (similar to condition (4)
of Proposition 2) is equivalent to each of the six equivalent conditions (1), ... , (6) (4')
Every
in the statement of Proposition 2.
t-divisible element in
Hn(C*)
is infinitely
t-divisible. Proof:
By Theorem 1',
divisible elements. saying that
"Hn(C*)
Hn(C*)
has no non-zero infinitely t-
Therefore condition (4') is equivalent to has no non-zero t-divisible elements", and
this latter is condition (2) of Proposition 2. Remark 2.
It is easy to verify Theorem l' of Remark 1 indepen-
dently of Theorem 4 by a more direct computational method. By Theorem 1, under the hypotheses of Theorem 1 if any integer and if in
M)
M = Hn (C*) ,
then
M)"
is
liml (precise ti-torsion i>O
is the set of t-divisible elements in
"liml (precise ti-torsion in i>O
n
M.
The group
also appears in Theorem 1 of
of Chapter II -and, by conclusion (3) of Theorem 1 of this chapter, and conclusion (1) of Theorem 1 of Chapter group "liml (precise ti-torsion in i>O (More about it in a later paper).
M)"
2, this
becomes more interesting
Therefore, the following
Proposition is of interest, since in most practical examples it
Cohomology of Cochain Complexes
555
gives a useful formula for this group. Proposi tion 5. Let
M
ment in
Let
A
be a ring with identity and let
be any left A-module such that every M
M
has no non-zero t-divisible
plication by
t): M ... M
t-divisible ele-
(E.g., this is the case
is infinitely t-divisible.
if, either
tEA.
is injective).
element~
2£ if (multi-
Then there is induced a
canonical isomorphism of abelian groups (or of A-modules if is in the center of (1)
[lim
1
t
A)
(precise ti-torsion in
M) ]
i>O
[lim (precise t
i
.
-tors~on
in
""...
M"t1M) ] .
i>O
(Here of course
,,"tiM"
means
"M" t I (image of
(or
M)",
equivalently, the cokernel of the natural homomorphism of abelian groups: for
(In the next Corollary, we write
"/\ n
"At".)
Corollary 5.1.
Let
A
be a ring with identity and let
an element of the center of such that every
A.
Let
M
t
be
be a left A-module
t-divisible element is infinitely t-divisible.
Then the following conditions are equivalent: (1)
liml (precise ti-torsion in
M)
= O.
i>O (2)
M"/M
(3)
u
u
~
has no non-zero t-torsion. A
M ,
tu = 0,
implies there exists
is the image of
of abelian groups: Corollary 5.2.
Let
A
element of the center of
v
v EM
(under the natural homomorphism
M ... M") .
be a ring with identity, let A,
such that
and let
M
t
be an
be a left A-module
Chapter 4
556
such that every t-divisible element in sible.
M
is infinitely t-divi-
Then the group ltml(precise ti-torsion in i>O
M)
is t-adically complete, and has no non-zero t-torsion. (Note:
In the case that
t
is not in the center of
this group need not be an A-module. group, since the group is a sub
~-algebra
of
A
~[tl-module,
generated by
Proof of Proposition 5:
But
t
A,
still acts on the
where
~[tl
is the
t).
We have the short exact sequence of
abelian groups: 0 .... (infinitely t-divisible part of
(1)
M)
->-
M ....
M/ (inf ini tely t-di visible elements)
->-
O.
For each integer
i~O,
sequence of functors
throwing through the exact connected
"~ f\.l~ [Tl /Ti • ~
if. [Tl
[Tl,
Tor 1
i
(,71 [T] /T ''l/ [Tl )
(where each of the three abelian aroucs in the sequence (1)
is regarded as a
plication by
t") ,
is "modding out by
if. [Tl-module by letting
T
and using the facts that
"
till
and that
"To~[Tl( 1
act as "multi-
0 /Ti • if. [Tl " [Tl ,if. [Tl/ Ti • if. [Tl) " ~
is "taking the precise ti-torsion," yields the exact sequence (the first four terms of the indicated exact sequence of six terms) : (2)
0 ->- (precise ti-torsion in (infinitely t-divisible part of
M) 1 .... (precise ti-torsion in M')
->-
->-
(precise ti-torsion in
(infinitely t-divisible part of
t-divisible part of where
M)
M)/t
i
- (infinitely
M),
M' =M/(infinitely t-divisible part).
The fourth group is
Cohomology of Cochain Complexes
557
clearly zero; therefore (2) defines a short exact sequence. i 2.. 0,
short exact sequences (2), for
The
def ine a short exact se-
quence of inverse systems of abelian groups indexed by the nonnegative integers.
Throwing that short exact sequence through
the right exact functor
liml, and using the fact that i>O precise ti-torsion in (infinitely
[ t-divisible part of
= 0,
] M)
since the maps in the indicated inverse systems are epimorphisms, it follows that we have a canonical isomorphism of abelian groups (or of A-modules if
t
is in the center of
liml (precise ti-torsion in
M) ':;.
'+0 1>
where
A)
liml (precise ti-torsion in M'),
itO
M' = M/ (infinitely t-divisible elements).
But since
clearly also
to prove the Proposition for
M it suffices to prove it for
By the hypotheses of the Proposition,
(t-divisible part of M)
(infinitely t-divisible part of
Therefore,
non-zero t-divisible elements.
M).
M'
Mr.
has no
Therefore, to prove the Propos i-
tion, it suffices to prove the Proposition in the case that M has no non-zero t-divisible elements; we assume this for the rest of the proof.
Then
M
is a submodule of
Also, we can regard Z[T]
M as being a
~. Z[T]-module, where
is the polynomial ring in one variable over
quiring that
T'
x=
Z[T]
by
T
and
t
t • x,
all
x EM.
Z,
Then replacing
if necessary, we can assume that
by reA
by
t
is in
Chapter 4
558
the center of Case 1.
M
.i'/M = 0,
A,
= i',
and that Le.,
t
is a non-zero divisor in
is t-adically complete.
M
A.
Then clearly
so the conclusion of the Proposition is that ' 1 ( prec~se , l ~m ti i~O
(1' )
'
-tors~on
,
~n
M) = 0,
which is what we must prove. Choose
P,
a free left A-module, and
phism of left A-modules. under the functor (2)
1/\ :
F"
"/\"
= M,
the image of
1
is an epimorphism
/\
Then
K
is the kernel of an A-homomor-
of t-adically complete left A-modules, and is therefore
phism
pA
t-adically complete. and
rI-
an epimor-
+ M.
K = Ker (1 ).
Let
Then since
1:P +M,
t
is the completion of a free A-module,
is a non-zero divisor in
FA
has no non-zero t-torsion.
of
F/\, K
A; therefore by Lemma 1.1.1 Since
K
is a left sub A-module
also has no non-zero t-torsion.
Therefore, if we
define C l = p/\, cO = K,
i C =0, and define
it-O,l,
dO :C O + C
l
to be the inclusion:
K ~F",
then
C*
is a cochain complex of left A-modules, and the hypotheses of Theorem 1 are satisfied.
Therefore the conclusions of Theorem
1 hold for the cochain complex of left A-modules
particular conclusion (3) for the integer that
C*, and in
n = 1, which implies
Cohomology of Cochain Complexes , ' 1 ( prec~se ti-torsion in l ~m
(3' )
i>l fE-divisible elements in But clearly
Hl(C*)~M.
Hl(C*»
559
~
Hl(C*)}.
And by the assumptions of Case 1,
is t-adically complete.
Hence
{t-divisible elements in
Hl(C*)~M
This observation, the fact that
M M} =0.
as left A-module
and equation (3') imply equation (1'), which proves Case 1. Case 2. tEA
General case.
(I.e.,
A
is a ring with identity,
is a non-zero divisor in the center of
A,
and
M
is a
left A-module having no non-zero t-divisible elements (so that M
is a submodule of
M' = M't»
.
Then we have the short exact sequence of left A-modules
Let
i
be any non-negative integer.
Then if we throw the short
exact sequence (3) through the homological exact connected sequence of functors (in fact, sequence of left
derived functors)
"(A/tiA) €I", "Tor1 (A/tiA, )", noting that A
"(A/tiA) €I N"
~ "N/tiN"
and
i "Tor1(A/t A,N) "",,"precise ti-torsion
A
in
N"
canonically as functors in
N
(i.
e., these two isomor-
phisms are specific natural equivalences of functors), we obtain the exact sequence of six terms (4 ) i
0 .... (precise ti-torsion in
M)""
(precise ti-torsion in M') . . , i , , M') .... M/tiM"" M' /tiM' (prec~se t -tors~on ~n M
(A/tiA) €I (M' /M) .... O. A
Since the natural mapping:
M/tiM .... MA /tiMA
is an isomorphism,
Chapter 4
560
it follows from the exact sequence (4 ) that i (5)
(M" !M)
is a t-divisible module,
and that for each integer
i >0
we have the short exact se-
quence (4
l
~)
0 .... (precise ti-torsion in
M) .... (precise ti-torsion
in
MA ) ....
" ti-torslon " "In (preclse
For each integer
i.::: 0,
"multiplication by
mapping from the short exact sequence
t"
(4 + ) i l
induces a into the short
exact sequence (4 ), and there is therefore induced a short i exact sequence of inverse systems of left A-modules (indexed by the positive integers), (6)
0'" (precise ti-torsion in M) i>O'" (precise ti-torsion in
ri') i>O'"
(precise
M"
The left A-module
ti-tor~ion
in
(M" !M)) i>O'" O.
is t-adically complete, and in par-
ticular has no non-zero t-divisible elements, and therefore also no non-zero infinitely t-divisible t-torsion elements. Therefore (7)
lJ,m(precise ti-torsion in
hO Also, the left A-module
M"
M")
= O.
obeys the hypotheses of Case 1.
Therefore, by Case 1 (and by equation (I') of Case 1), (8)
" " . " 1 ( preclse t i -torslon In I ~m
M1\) = 0 •
i>O Throwing the short exact sequence (6) through the exact connected sequence of functors
"lim" ,
ito
yields an exact sequence
Cohomology of Cochain Complexes
561
of six terms, a portion of which is the exact sequence (9)
-+
l,im(precise ti-'torsion in r.f) -+ lim (precise ti_ i~OI\ dO 1 i!O.1 torsion in (M /M)~lim (precise t -torsion in 1 i i'::'°A M) -+ lim (precise t -torsion in M·) -+ ••• i>O
substituting equations (7) and (8) into equation (9), we see that the map
dO
(from the zero'th coboundary in the connected
sequence of functors) of equation (9) is an isomorphism of left A-modules: (10)
lim (precise ti-torsion in (M' /M))~ i'::'°liml(preCiSe ti-torsion in i>O
M),
which completes the proof of Case 2, and therefore also the proof of the Proposition. Proof of Corollary 5.1.
By equation (5) in the proof of Case
2 of Proposition 5, we have that i.e., every element of fore
M'/M
M'/M
M'/M
is a t-divisible module,
is infinitely t-divisible.
has no non-zero t-torsion iff
infinitely t-divisible, t-torsion.
M'/M
There-
has no non-zero,
This latter occurs (as for
any left A-module) iff
lim (precise ti-torsion in M' /M) = 0. i>O By the conclusion (1) of Proposition 5, this latter occurs iff
condition (1) holds.
Thus, condition (1) of Corollary 5.1 is
equivalent to condition (2) of Corollary 5.1. (2)~(3),
Since obviously
this proves Corollary 5.1.
Froof of Corollary 5.2.
If
N
is any left A-module, then it is
easy to see that the left A-module R = lim (precise ti-torsion in N) i>O
Chapter 4
562 has no non-zero t-torsion.
Also,
R,
being the inverse limit
of t-adically complete A-modules, is itself t-adically complete. Applying this observation to the A-module
N=
M'IM,
and using
the conclusion of Proposition 5, we obtain the conclusion of Corollary 5.2. Remark:
Do Theorem 4, the Lemma following Theorem 4, Propos i-
tion 5, Corollary 5.1 and Corollary 5.2 generalize to abelian categories?
The answer is "yes".
A be
More precisely, let
any abelian category such that denumerable direct products exist and such that the denumerable direct product of epimorphisms is an epimorphism (i.
e.,
and such that the functor "denumerable
direct product" preserves epimorphisms). Theorem 4 (generalized).
Let
t:M'" M be any endomorphism.
Then
M be an object in
A
and let
Then we have an exact sequence of
five terms (1) as in the conclusion (1) of Theorem 4.
(Where,
as usual, "(infinitely t-divisible part of M)", "(t-divisible part of M)", etc., are interpreted in the obvious way, as in Chapters 1 and 2). Lemma (generalized).
In the statement of the Lemma following
Theorem 4, replace the word "abelian groups" by "objects in and "subgroups" by subobjects". (Where of course "completion of the subgroups Theorem l' .
A",
Then the Lemma remains valid. NO
for the topology given by
N;, i> 0" is replaced by "lim (N IN.) .") ... itO 0 ~ (generalized}. Let C* be a (z-Tndexed) cochain
complex of objects and maps in the category be an endomorphism of the cochain complex
A C*.
the hypotheses of Theorem 1 (generalized) hold.
and let
t = t*
Suppose that Then conclusion
(2') of Theorem l' holds (where "infinitely t-divisible part" is defined as in Chapter 1).
Cohomology of Cochain Complexes Proposition 2'
(generalized).
563
The hypotheses being as in Propo-
sition 2 (generalized), then the six equivalent conditions of Proposition 2 (generalized) are all equivalent to condition (4') of Proposition 2'. proposition 5 (generalized). A
gory
and let
t:M .... M
divisible part of
M)
Let
M
be an object in the cate-
be an endomorphism such that the (t-
coincides with the (infinitely t-divisible
n 1m ti=Im (lim ( ...~ M~M~M) .... M». i>O i>O Then conclusion (1) of Proposition 5 holds-(where of course
part).
(I.e., such that
e.g. "(precise ti-torsion in
M)"=Ker (t i )", etc.).
Corollary 5.2 (generalized).
Under the hypotheses of Proposi-
tion 5 (generalized), we have that the object (1)
liml (precise ti-torsion in
M)
PO in the category
A is complete for the endomorphism induced by
t, and also that the endomorphism induced by
t
of the object
(1) is a monomorphism. However, the proof of Corollary 5.1 appears to require a stronger axiom on the abelian category (Intro., Chap. 1, sec. 7). Corollary 5.1 (generalized).
A
Suppose that the abelian category
has, in addition to the previously stated property, the
property that, whenever objects and maps in
(Ai,aij)i,j~O
is an inverse system of
A indexed by the non-negative integers
then a + ,i is an epimorphism, all integers i ~ 0, i l the natural mapping: (lim Ai) .... A is an epimorphism (it is eO i~O quivalent to say that, for every such (A. , a· .). . 0' we have 1 1J 1,J;: such that
that
liml Ai = 0) • i>O
(Otherwise stated:
In stating the general i-
zations of Theorem 4, ... , Corollary 5.2, our assumption on the
Chapter 4
564
A was "(P.l)" of [E.MJ; but for Corollary 5.1
abelian category
we also need the stronger axiom" (P.2)" of [E.M.l.
(To the best
of my knowledge, no one knows whether or not there exists an
A that obeys (P.l) but not (P.2».
abelian category
Then the
three conditions stated in Corollary 5.1 are equivalent; where "precise ti-torsion" means "Kernel of
till, "has no non-zero t-
torsion" means "t induces a monomorphism", and condition (3) becomes: (3)
Let
¢:M
-..r1'
be the natural map.
Then the (precise t-torsion in in the image of
r1')
is contained
¢.
(The reason for the stronger hypotheses on the abelian
A in the generalization of Corollary 5.1 is that in
category
proving that (1)
~(2),
we need to know that the mapping:
(l~m (precise ti-torsion in
r1' 1M»
.... (precise t-torsion in
r1' 1M)
i~O
is an epimorphism, and here the maps in the inverse system in question are epimorphisms; so that we require exactly the stronger hypotheses (P.2) on the abelian category that (2)
~(l)
remains valid if only (P.l) holds, and
requires no hypothesis (not even (P.O» A.
(Where
M,
A.
r1'
abel ian ca tegory
are any objects and A) - use
The proof (2)~(3)
on the abelian category M -..
r1'
is any map in any
the exact imbedding theorem [I. A. C . 1) •
(However, if we modify condition (2) of Corollary 5.1 to read.
"(2')
r/'/M
has no non-zero t--torsion that is infinitely
t-divisible", then the resulting generalization to abelian categories remains valid for abelian categories obeying the milder
Cohomology of Cochain Complexes assumption (P.l).)
A.
categories
tha t
1T i
Also, Lemma 1.1.1 generalizes to abelian
(One must replace
the form
565
"?
[tl (I)/\t"
by objects of
with endomorphism the "shift map"
+l o t =
1T i
projection, all
i.::.O,
'
ITO,ot=O,
i.:::. 0, and where
where
AE A
1T. 1.
t
such
is the i'th
is any object).
Does Theorem 1 remain valid if one deletes the hypothesis til :C n ...,. C
(2), that "multiplication by gers
n?
The answer is "yes".
n
is injective, all inte-
At least, if this hypothesis is
deleted, then most of the conclusions of Theorem 1 continue to hold.
The same is true for Theorem l' of Remark 1 following the
proof of Theorem 4. Theorem 6. C*
be a
Let
That is,
A
be a ring with identity, let
(~-indexed)
tEA
and let
cochain complex of left A-modules such
that (1)
n C
is t-adically complete, all integers
n.
Then
most of the conclusions (1)-(4) of Theorem 1, and also conclusion (2') of Theorem l'
(of Remark 1 following the proof of Theorem
4) continue to hold; that is, we have that: (2)
for every integer
n,
Hn(C*)/(t-divisible elements)
is t-adically complete. (2') For every integer
n,
Hn(C*)
has no non-zero infi-
nitely t-divisible elements. (3)
For every integer
n,
there are induced natural iso-
morphisms of abelian groups (or of left A-modules if t
is in the center of
A)
n
n
H (C*) / (t-divisible elements", H (C*) (3') For every integer group of equation
n,
/\t
.
we have an epimorphism from the
(3) onto
Chapter 4
566
lim [Hn(C*/tic*)].
i>O (4)
Also, for every integer
n,
there are induced natural
isomorphisms of abelian groups (or of left A-modules if
t
is in the center of
(t-divisible part of
A):
Hn(C*))
~ liml[precise ti-torsion in
Hn(C*)].
i>O (5)
Also, for every integer
n,
the subgroup of
Hn(C*)
described in conclusion (4) is contained in the subof
group
Notes 1. that
n H (C*).
Notice that, by Corollary 1.2 of Chapter
(lim l Hn-l(C/tic*)]
3, we have
is naturally identified with a sub-
ito
group of- Hn(C*), as alluded to in equation (5) above. by Corollary 1.2 of Chapter
all integers
n > O.
Also
3, we have the short exact sequence
The epimorphism of equation (3') is induced
by the epimorphism of this short exact sequence. 2.
Let
n
be an arbitrary fixed integer.
(t-adically complete, left A-submodule)
Then if the
Im(dn:C n ... c n + l )
has no
non-zero t-torsion elements, then the proof of Theorem 6 below shows that, for that integer is an isomorphism.
n,
the epimorphism of equation (3')
I.e., that for that integer
subgroups (the one of conclusion (4) and
n,
the two
liml Hn-l(C*/tic*))
i>O described in conclusion (5),coincide. Remark.
However, in the context of Theorem 6, we state no ana-
logue of Corollary 1.1.
(Since Bockstein spectral sequences
567
Cohomology of Cochain Complexes
don't make sense unless hypothesis (2) of Theorem 1 holds - although, by using "percohomology" as we shall define it in Chapter 5, a Bockstein spectral sequence can be defined, and an analogue of Corollary 1.1 can be stated under the (weaker) hypotheses of Theorem 6.
This analogue of Corollary 1.1 is actually
the corollary to another (different - and more shallow) generalization of Theorem 1 that holds under the same hypotheses as Theorem 6,
(if also the element
tEA
is in addition assumed to be
a noa-zero divisor), namely, to Theorem 6' of Remark 4 below. Note 3.
Also, as in the Note to Theorem 1,
(and also Theorem
1', see the preceding Remark), Theorem 6 above generalizes to abelian categories s.t. den. dir. products exist and are exact. That is, let
A be any abelian category such that denumer-
able direct products exist and such that the direct product of denumerably many epimorphisms is an epimorphism (i.e., and such that the functor "denumerable direct product" preserves epimorphisms).
Let
C*
be an arbitrary cochain complex, indexed by
all the integers, in th,:! abelian category
A,
be an endomorphism of the cochain complex
C*.
n C
is complete for the endomorphism induced by
and let
t = t*
Suppose that (1) t,
all integers
n. Then the six conclusions,
(1), (2'), (3), (3'), (4) and (5) of
Theorem 6 all hold. (Where, terms like "complete with respect to an endomorphism", fIt-divisible part", "completion with respect to an endomorphism", etc., are defined as in Chapter 1.)
(The proof of
this Note is exactly the same as that of the Theorem.) Note 4.
Theorem 6 is an improvement of both Theorem 1 and
568
Chapter 4
Theorem 1'.
These latter were used to prove Proposition 2 and
Proposition 2'.
Theorem 6 implies the following partial improve-
ment of Proposition 2 and Proposition 2'. Proposition 2".
Under the hypotheses of Theorem 6, if
any fixed integer, then the conditions (1),
(2),
n
is
(4), and (5) of
Proposition 2, and also the condition (4') of Proposition 2', are all equivalent to each other.
Also, in this case, conditions
(3) and (6) of Proposition 2 are equivalent to each other, and imply the other conditions of Proposition 2. Proof of Theorem 6: of
A
Replacing the ring
generated by the element
t
A
by the subring
if necessary, one immediately
reduces the proof to the case in which the element center of the ring since hypothesis
A.
~[t]
t
is in the
Then by Corollary 1.2 of Chapter
(1) of Theorem 6 holds, for each integer
3, n
we
have the short exact sequence: (5)
o+liml [Hn-l(C*/tiC*)]+Hn(C*)+ i>O lim [Hn(C*/ti(C*)] +0. i>O
Clearly, from equation (5), it follows that conclusion (3') of Theorem 6 follows from conclusion (5) of Theorem 6. Fix an integer plex of
C*
n E;r,
and let
D*
be the subcochain com-
such that
I
ci , n n :er (d : C
i~n
+
C
n+l
),
- 1,
i = n,
i>n+l.
Then the natural map induces an isomorphism: Therefore to establish conclusions (1),
Hn(D*) ~Hn(C*).
(2') and (3) for the co-
Cohomology of Cochain Complexes chain complex for
D*.
C*,
it suffices to establish these conclusions
Notice that
D*
obeys all the hypotheses of the Theon l D + = O. By Note 2 to the Theorem,
rem, and in addition that for such a Hn(D*)
D*,
569
it is asserted that the two subgroups of
described in conclusion (5) coincide.
But, in the short
exact sequence (5' )
established in Corollary 1.2 of Chapter
3, the third group is
a t-adically complete left A-module (being an inverse limit of t-adically complete left A-modules - Hn(D*/tiD*) complete since it is annihilated by
ti,
is t-adically
all integers
i~O).
Therefore, both conclusions (1) and (3) of Theorem 6 for (and therefore also for
C*)
D*
would follow if we knew that, in
the exact sequence (5'), the first group is the t-divisible part of the second group, all
integer~
n.
But this would follow
from conclusion (5) of Theorem 6 as modified by Note 2.
There-
fore, to prove Theorem 6, it suffices to prove both conclusion (2') and conclusion (4) and (5) of Theorem 6 and Note 2 to Theorem 6. Equations (2'), (4) and (5), and Note 2, are together equivalent to: (6)
both For each integer
n,
Hn(C*)
has no non-zero infinitely
t-divisible elements, and the t-divisible part of Hn(C*) ~ liml(precise ti-torsion in i>O and
(7)
For each integer ' 1 ( prec~se , l ~m ti i~O
Hn(C*»,
we have a canonical monomorphism:
n, '
-tors~on
,
~n
570
Chapter 4
Ij,mlHn-l(C*/tiC*). i>O
If
r=rm(dnc*:Cn+cn+l)
is
without non-zero t-torsion, then this monomorphism is an isomorphism. We prove equations (6) and (7) separately. First, every A-module where
T· x
= t • x,
all
N
can be regarded as a
x E'N.
Therefore replacing
if necessary, we can assume that
t E center of
~[T)-module,
A by
A,
~
[T)
and that
t
is a non-zero divisor. Part 1.
Proof of equation (6):
Fix an integer n, and let M = Hn (C*). Let Dl = Ker (dn:C n + Cn + l ) . Then, since by hypothesis (1) of the Theorem n n C and c + l are t-adically complete, we have that Dl is t-adically complete.
Define
the A-homomorphism induced by
DO = Cn - l ,
and let d: DO + Dl be d~:l:cn-l + Cn Then M = Coker (d),
so that we have an exact sequence of left A-modules: d 1 Do +D +M+O,
(8)
where
DO Let
and
Dl
are t-adically complete.
F be a free left A-module and let
morphism of left A-modules. plete, functor,
Dl = (Dl),,'t,
Then since
Dl
TT:F + Dl
be an epi-
is t-adically com-
we have that the image of
TT
under the
"t-adic completion", is an epimorphism of (complete)
left A-modules
.
TT" . F"
+
and modules:
Dl Tf
. 1
1\
=Tf
•
Then we have a diagram of left A-
Cohomology of Cochain Complexes
with
TIl
an epimorphism.
And
0°,0
1
and
Fl
571
are all t-adi-
cally complete. I
Let
F O _ Fl D0 xl'
the fiber product of this diagram.
o
Then we have a commutative diagram:
(9)
Since
TI
1
is an epimorphism, so is
°
TI .
is the kernel of
a homomorphism of t-adically complete left A-modules - namely, FO = Ker y,
where
y :0° x Fl .... 0 1
is the homomorphism of left
A-modules y = TIl
0
TI 1 - do F
where
TI 1:0
0
011 XF .... F
and
° TI 0:0° x F
l
.... D°
are the projections.
o
F
Therefore
7f
'FO,
being the kernel of an A-homorphism of t-adi-
cally complete left A-modules, is likewise t-adically complete. Consider the commutative diagram of left A-modules, with an exact right column and with exact rows:
Chapter 4
572
°t
0
t
O-M~===M-O
t Fl
(10)
1 Tf)
t D~O
1 °i a
'F O
Tf
d
)DO~O
(where the rightmost column is the sequence (8), and where the 1
map
Fl .... M
is the composite:
F l .2!..,.D l .... M).
Since the commuta-
tive square (9) is a fiber product square, it follows by diagram chasing that the leftmost column in the commutative diagram (10) (Proof:
is exact.
F
1
being a composite of two epimor-
-+M,
phisms, is an epimorphism. the composite:
The composite:
°
'FO~DO~Dl""M,
of the right column of (10). zero in
M,
'FO .... Fl .... M equals
which is zero by exactness
Finally,
if
fl E Fl
maps into
then by exactness of the rightmost column (and
commutativity of the top square) in the diagram (10) we have that there exists
dOEDO
such that
Tfl(fl) =d(dO)
in
Dl.
But then, since the commutative square (9) is a fiber product square, there exists a unique element a('fO) =f l
and
TfO('fO) =dO.
'fOE 'FO
In particular,
such that a('fO) =f l .)
Therefore, we have constructed an exact sequence of left Amodules,
such that Fl
and
Fl
are t-adically complete, and such that
is the t-adic completion of a free left A-module.
element of
'FO
A,
tEA
is a non-zero divisor in
A
and is in the center
it follows by Lemma 1.1.1 that the A-module
non-zero t-torsion.
Since the
Fl
has no
Cohomology of Cochain Complexes Let
pO
be a free left A-module and let
epimorphism of left A-modules. complete, if we let
FO
=
FO
A
Then since
573
ljJ:p o . . 'FO
'FO
then the image of
be an
is t-adically ljJ
under the
functor
"t-adic completion" is an epimorphism of left A-modules:
Letting
d = 8
0
ljJ
A
and considering exactness of the sequence (II),
we obtain an exact sequence
°
F _dF 1 .... M .... O,
(13) where
FO
and
and therefore
Fl
are both completions of free left A-modules,
FO
and
Fl
are both t-adically complete, and Define
with no non-zero t-torsion by Lemma 1.1.1. i d F * = 0,
it-O,l,
it-O.
Then
F*
is a
F
i
=
0,
(non-nega ti ve)
cochain complex of left A-modules that obeys the hypotheses (1) and (2) of Theorem 1, and
Hl(F*) ~M.
conclusion (4), for the case (t-divisible part of
n
= I,
But then, by Theorem 1, if follows that
M) ~ liml (precise ti-torsion in itO
And by Theorem 1', conclusion (2'), applied to the case M
has no non-zero infinitely t-divisible elements.
M=Hn(C*), Part 2.
n = 1, Since
this completes the proof of equation (6).
Proof of equation (7).
Fix an integer Case 1.
M).
C
i
= 0,
n,
and let
all integers
dn-l:cn-l .... cn
n M = H (C*).
it-n-l,n,
and
is a monomorphism.
Then we have the short exact sequence of left A-modules (8)
o . . Cn-l
.... C
n .... M .... O.
Chapter 4
574 Let
i
be a non-negative integer.
Then throwing the short
exact sequence (8) through the homological, exact connected sequence of functors (in fact, system of left " (A/tiA)
~ :', "Tor1 (A/tiA, )"
derived functors)
yields an exact sequence of
A/tiA-modules of six terms, a portion of which is the exact sequence
(9)
••• -+-
(precise ti-torsion in
Cn)
(precise ti-torsion in
M)
+
~
(Cn-l/tiCn-l) + Cn /tiC n + ••• Since the kernel of the mapping Hn - l (c*/tic*)
(since
(Cn-l/tiCn-l)
Cn - 2 = 0),
+
(Cn/tiC n )
is
the exact sequence (9) implies
that we have an exact sequence (lOi)
••• -+
ti-torsion in
(precise
(precise ti-torsion in Hn - l (c*/tic*) where
a
cation by
is induced by t"
6.
+
Cn)
+
M) ~
0,
For each integer
induces a map from the sequence
i
~
0,
"multipli-
(lOi+l)
into
(lOi); we therefore obtain a similar exact sequence of inverse systems of left A-modules indexed by the non-negative integers. Throwing that sequence through the right exact functor
liml i>O
yields the exact sequence
(11)
[liml(precise ti-torsion in i!.°l [lim (precise ti-torsion in i>Ol . [IIm Hn - l (e*/t~e*)] + 0.
en)] + M)] +
i>O But since
en
is a t-adically complete left A-module,
(by the
Cohomology of Cochain Complexes hypotheses of this Theorem),
en
575
obeys the hypotheses of Propo-
sition 5, and therefore by Proposition 5 [lim
(12)
l
en)] ~
(precise ti-torsion in
ito
.
[lim (precise t~-torsion in
(eN'/e n »].
i>O n C
But since
eM /C
n
=
is t-adically complete,
M
C
=0
en,
therefore
and therefore the group on the right side of equa-
0,
tion (12) is zero. of equation (12).
Therefore so is the group on the left side Substituting into the exact sequence (11), we
see that the second A-homomorphism in the sequence (11) is an isomorphism (precise ti-torsion in
(13)
M)] ....
Hn-l(C*/tic*)], which proves equation (7). Case 2.
i C = 0, all integers
i
~ n - 1, n.
Then we have an exact
sequence of left A-modules (8)
cn- l
n-l
..2.-C n .... M .... O.
and
Then
Dn-l ,
being the image
of an A-homomorphism of t-adically complete left A-modules, is t-adically complete, and since complete.
Define
the inclusion.
D
Then
i
n n D = C ,
n D
is also t-adically
= 0,
D*
is a cochain complex of left A-modules
obeying the hypotheses of Case 1, and
M~H
n
(D*).
Therefore, by
Case 1, we have a specific isomorphism of left A-modules (9)
(precise ti-torsion in Hn-l(D*/tiD*)].
M)] ""
Chapter 4
576
Let
K
= (kernel of the natural epimorphism:
Ker(d n - l ) =Hn-l(C*),
and for each integer
(Kernel of the epimorphism:
C
i >0
n l n l - ->- D - )
let
K. = 1
(Cn-l/tiCn-l) ->- (Dn-l/tiDn-l)).
Then
we have a short exact sequence: O+K->-C n-l +D n-l +0, and therefore an exact sequence (since
II
(A/tiA) 0
is a right
n
A
exact functor)
Therefore also of i,
let
such that
K.
1
K,
all integers
.K*
1
is a quotient A-module of i > O.
K/tiK,
and therefore
For each non-negative integer
be the unique cochain complex of left A-modules
j 0 iK-- I
all integers
j~n-l,
.K
1
n-l
= K .• 1
Then we
have a short exact sequence of cochain complexes of left A-modules: (10) j~n-l
j = n - 1 ,
a portion of the long exact sequence of cohomology of the short exact sequence of cochain complexes (10) is the exact sequence of left A-modules:
For each non-negative integer the sequence (lli+l)
i,
we have a natural map from
into the sequence (lli)' and we therefore
obtain an exact sequence of inverse systems of left A-modules
Cohomology of Cochain Complexes indexed by the non-negative integers. . h t exact f i l l ~im lll r~g unctor i>O (12)
K.]
~
. Id s y~e
577
Throwing through the
t h e exact sequence
->- [li ml Hn-l(C*/ti(c*)]->i>O
Hn - l (D*/tiD*)] ->-
o.
But we have observed that
Ki
is a quotient A-module of
all non-negative integers
i,
whence
K,
liml K. = O. i>O ~
(13)
substituting equation (13) into the exact sequence (12) we see that the second map in the sequence (12) is an isomorphism of left A-modules (14) Equations (9) and (14) imply equation (7). i C = 0, all integers
Case 3.
cochain complex of that
Di=O,
C*
i > n + 1.
such that
all integers
D
n-l
i;;o!n-l, n.
Then let =C
n-l
Let
0*
be the sub-
,
and such E*=C*/D*.
Then
i < n - 2
and we have a short exact sequence of cochain complexes of left A-modules: (8)
O->-D*->-C*->-E*->-O.
The cochain complex Hn(D*)
(=Hn(C*»
=M.
D*
obeys the hypotheses of Case 2, and
Therefore, by Case 2, we have a canonical
isomorphism of left A-modules
578
(9)
Chapter 4 M») ~ [liml Hn-l{D*/tiD*»).
[liml (precise ti-torsion in
i>O
i>O For each integer
the short exact sequence:
j,
splits (since in fact i f j
tity of c j j map C ->- E
j
and
E = 0;
the map
D
and if,
j~n-2
then
is the identity of
through the additive functor every non-negative integer
is exact.
j
j2:. n - l
II
i
j
C ). (A/tiA)
->-
C
j
is the idenj
D = 0
and the
Therefore, throwing
~ ", we have that for
that the sequence:
Therefore, for every integer
i 2:. 0,
we have the
short exact sequence of cochain complexes of left
(A/tiA)-
modules:
A portion of the long exact sequence of cohomology of this short exact sequence of cochain complexes is the exact sequence of left
(A/tiA)-modules: (10)
• • • -+
2 . an - 2 1 . Hn - (E* /tlE* ) _ H n - (D* /tlD*)
->-Hn-l(C*/tiC*) ->-Hn-l(E*/tiE*) ->- '" all integers
i > O.
· Bu t , Slnce
all integers
i 2:. 0,
and that
Hn - 2 (E*/t i E*) (A/tiA)-module
E n - l = 0,
,
we have that
is a quotient (A/tiA)-module of the
En-2/tiEn-2 (=Cn-2/tiCn-2),
and therefore that
Cohomology of Co chain Complexes (12)
Equations
579
i n 2 H - (E*/t E*)
is a quotient left A-module of the
left A-module
En-2 ,
(11) and (12)
all integers
i.
substituted into equation (10) yields
the exact sequence of left A-modules
For each integer
i > 0,
we have the natural mapping from the
sequence (13 + ) i l
into the sequence (13 ). i
We therefore obtain
an exact sequence of inverse systems of left A-modules indexed by the non-negative integers. "liml" ~ i>O
f unc t or (14)
Throwing through the right exact
. Id s th e exac t Yle
[lj,m l E n i>O
2
sequence
] .... [lj,m l Hn - l (D*/tiD*)] .... i>O
[lj,m l Hn - l (C*/tic*)] .... 0 i>O Since the inverse system Ij,m i>O
l
n 2 E - = O.
n 2 "E - "
is constant, we have that
Substituting into equation (14), we see that the
second map in the sequence (14)
is a specific isomorphism of
left A-modules (15) Equations (9) and (15) Case 4. of
C*
General case.
imply equation (7). Let
D*
be the quotient cochain complex
such that
j.::,n
Let
E*
D*-+C*.
be the kernel of the epimorphism of cochain complexes: Then
580
Chapter 4 j~n
j>n+l.
The cochain complex
D*
obeys the hypotheses of Case 3.
fore, by Case 3 we have a canonical isomorphism of left
ThereA-module~
We have the short exact sequence of cochain complexes of left A-modules (9)
O+E*+C*+D*+O. i E z, the sequence
For each integer
splits (since
Ei
=0
for
i < nand
Di
=0
for
Therefore, throwing through the additive functor
i
~n + 1).
"(A/tjA)
@
II
A
we obtain a short exact sequence of cochain complexes of left (A/tjA)-modules:
all integers
j
~
O.
A portion of the long exact sequence of
cohomology of this short exact sequence of cochain complexes is the exact sequence
But ,
; nc e S ...
Ej
=0
f or
J.
~
n,
...;t follows that
Hn-l(E*/tjE*)
Cohomology of Cochain Complexes n
.
H (E*/tJE*) =
o.
581
Substituting into the last long exact sequence,
it follows that, for every integer
j
~
0, that the natural map
induces an isomorphism:
Throwing through the functor
liml, i>O ral mapping induces an isomorphism: (10)
it follows that the natu-
[liml Hn-l(C*/tjc*) J ~ [liml Hn-l(O*/tjo*) J. i>O i>O
A portion of the long exact sequence of cohomology of the short exact sequence of cochain complexes (9) is the exact sequence n-1
(11)
•••~Hn
n
(E*) -+ Hn (C*) -+ Hn (0*) ...£-H n + 1 (E*) -+
Hn+l(C*) -+ ..• We have that (12)
En = 0,
and therefore
Hn(E*) = 0,
and
Hn + 1 (E*) =Ker (d~~1:En+1-+En+2). E
But
En+l=C n + 1 ,
n+2 _ Cn+2 dn+1 _ dn+l , E* - C* •
Therefore
Ker (d~~l: En + l -+E n + 2 ) =Ker (dg~l: c n + l -+C n + 2 ),
therefore the kernel of the natural mapping: is canonically isomorphic to we let
n+l 1 = 1m (d *: C -+ C ), n
c
n
and
n n H + l (E*) -+ H + l (C*)
n n l 1m (d~*: C -+ c + ).
Therefore, if
then substituting this last obser-
vation and equation (12) into equation (11) yields the short exact sequence (13) where
0-+H n (C*)-+H n (D*).§.1-+0,
n n l 1 = 1m (d~*: C -+ c + )
and
<5
is induced by a coboundary
58;>
Chapter 4
(in fact, into
1m
n l is the natural map from Coker (d~:l: C -
0
(d~*: Cn
-+
n l C + ».
-+
Cn)
The monomorphism in equation (13)
implies that the natural map induces a monomorphism, (14)
Since
C*
(t-divisible part of
n H (C*) )c.->
(t-divisible part of
Hn(D*».
and
D*
both obey the hypotheses of this Theorem, by
equation (6) applied to (15)
C*
and to
(t-divisible part of [llm i>O
l
D*
we have that
n H (C*) ) ""
(precise ti-torsion in
Hn(C*»],
and (16)
(t-divisible part of
n H (D*»
""
[liml (precise ti-torsion in i>O Equations (8),
(10),
(14),
(15)
Hn(D*»].
and (16) imply that we have a
natural monomorphism: (17)
Ilml (precise ti-torsion in i>O
Hn(C*»
~
liml Hn-l(C*/tic*). i>O This completes the proof of equation (7). On the other hand,
is such that
1
by equation (13), if
1 = Im(d~*: Cn
-+
Cn + l
has no non-zero t-torsion, from equation (13),
it follows that the natural map is an isomorphism (precise ti-torsion in
Hn(C*»~
(precise ti-torsion in
Hn(D*»,
all integers
i > O.
Throwing through the functor
liml, i>O
we see
Cohomology of Cochain Complexes
583
that in this case the natural map: (18)
[lim i>O [lim itO
1
(precise ti-torsion in
Hn(C*» 1 ->-
1
(precise ti-torsion in
Hn (D*) ) )
is an isomorphism.
Equations (8),
(10) and (18) therefore imply
Note 2.
Q.E.D.
Corollary 6.1. Let
C*
Let
A
be a ring with identity and let
tEA.
be an (arbitrary, Z-indexed) cochain complex of left
A-modules, and let
c*" = c*"t.
Then for every integer
n,
there is induced a natural mono-
morphism of abelian groups (or of left A-modules if center of
is in the
A), (t-divisible part of
(1)
t
If for some fixed integer
n,
Hn((c*)A)}c.t[lj,m l Hn-l(C*/tiC*)l. i>O Cn + l has no non-
we have that
zero t-torsion, then for that fixed integer
n
the monomorphism
(1) is an isomorphism. If, in addition, the endomorphism "multiplication by til
:C
n
ger
->-
n C
n
is injective, all integers
n,
then for every inte-
there is induced a canonical isomorphism of abelian
groups (or of left A-modules if
t
is in the center of
A)
of
each of the groups in equation (1) to the group (2)
Note:
" 1 (preclse " t i -torslon " " ln I !m i>O
Corollary 6.1 generalizes abelian categories:
Let
A be
an abelian category such that denumerable direct products exist and such that the functor "denumerable direct product" preserves
584
Chapter 4
epimorphisms.
Then
Corollary 6.1 (generalized).
Let
C*
be an (arbitrary, z-
A,
indexed) cochain complex of objects and maps of t'" t*
be any endomorphism of
C*.
Then the conclusions of
(With phrases like nt-divisible" and "in-
Corollary 6.1 hold.
jective" interpreted in the obvious way, as in Proof.
and let
Chapte~
1.)
We have that the natural map is an isomorphism:
(C*/tic*)
~ (C*A/tic*A),
all integers
i.
Therefore, conclusion
(1) of Corollary 6.1 follows from conclusion (3) of Theorem 6, applied to the cochain complex n l c +
c./I.
If for some integer
n,
is with no non-zero t-torsion, then it follows from Lemma n C +l
1.1.1 that
A
also has no non-zero t-torsion.
by Note 2 to Theorem 6, for that integer
n
Therefore
the monomorphism
(1) is an isomorphism. If the endomorphism "multiplication by jective for all integers
n,
t" :C
n
->-
n C
is in-
then the hypotheses for the exact
sequence (I. 8) of [P.P.WC.] hold - i. e., the hypotheses of Theorem 1 of Chapter 2
hold.
rem 1 of Chapter (2)
Therefore we have conclusion (2) of Theo-
2, i.e., we have an isomorphism:
Itml [H n - l (C*)] "';. [liml (precise ti-torsion in
i>O all integers
Hn (C*))]
i>O n.
This completes the proof of the Corollary.
Q.E.D. Remarks 1.
Let
C*
be any
plete left A-modules, where let
tEA.
z-indexed cochain complex of comA
is a ring with identity, and
Then, by Theorem 6, applied to
sion (4), the
C*A = C*A t,
conclu-
leftmost group in conclusion (1) of Corollary 6.1
is canonically isomorphic to
Cohomology of Cochain Complexes (2')
liml (precise ti-torsion in
585
Hn(C*A».
i>O Therefore, an equivalent way to state the second conclusion of Corollary 6.1 is to say that, if is injective, all integers
n,
n t": C
"multiplication by
-+
n C
then the natural map from the
group (2) of Corollary 6.1 into the above group (2')
is an iso-
morphism. 2. be a
Let
A
be a ring with identity, let
(~-indexed)
tEA
and let
cochain complex of left A-modules.
Suppose
that "multiplication by integers valid?
n;
tll:C
n
-+
cn
C*
is not one-to-one for all
then is conclusion (2) of Corollary 6.1, still
The answer is "no", as is seen by the following counter-
example. Example 1.
Let
M
n M"" H (0*)
and is such that (~-indexed)
part of
for some integer
n
and some
cochain complex of complete left A-modules
(Such modules mark 7.)
be any left A-module that is not complete
0*.
exist, see Examples 1 and 2 below, after Re-
M
Then by conclusion (1) of Theorem 6, the (t-divisible M)"I O.
Also, by conclusion (4) of Theorem 6,
(t-divisible part of
M) "" liml (precise ti-torsion in
M) •
So
Therefore (1)
[lim l i>O
(precise ti-torsion in
On the other hand,
MA
M)
1 "I
O.
is t-adically complete, and therefore
has no non-zero t-divisible elements, so by Proposition 5 (2)
Chapter 4
586
[lim (precise ti-torsionin
i>O Let
C*
(~)i\) 1 = o. M
be the cochain complex such that i 'I O.
integers
i C = 0,
cO = M,
all
Then
Therefore, by equations (1) and (2) of this Example, and by Remark 1, the conclusion (2) of Corollary 6.1 does not hold for C* . Also, it is not difficult to construct examples in which all the hypotheses of Theorem 6 hold, yet the monomorphisms described in conclusion (5) of Theorem 6 are not all isomorphisms. Example 2.
Let
field and let
be a complete discrete valuation ring not a
0 t
be a generator for the maximal ideal of
be the completion of a free
Let
rank having for
for
O-module of denumerable
O-basis the elements
the completion of a free O-basis the elements
xi'
i > O.
r i'
Let
O-modules
is isomorphic as
O/tiO,
as
R.
~
O-module to
d
1
:c l
....
Define
Let
CO
be
C
2
R , i
be the comple-
i > O.
where
i;:O,
R.
~
be a generaDefine
c2 all integers all integers
ci=O,
O.
and
by requiring that that
>
and let
O-module, all integers
dO:C°-+C l
i
O-module of denumerable rank having
tion of the direct sum of the
tor of
O.
all integers
Then we have a cochain complex hypotheses of Theorem 6.
i;:O,
and
i > 0.
i'lO,1,2. C*
of
O-modules obeying the
However, if we define
D*
by requiring
Cohomology of Cochain Complexes that
0*
be a quotient cochain complex of
C*
587
and that
i = 0,1, i = 2,
then the element Hl(O*)
X
t
oE C
l
=0
1
defines a divisible element in
unequal to zero.
However, an explicit computation shows that
G = Hl (C*)
is
not finitely generated, has no non-zero t-torsion and is tadically complete.
In particular,
t-divisible elements.
Hl(C*)
Considering the proof of Case 4 of
Theorem 6, we see that (t-divisible part of
~
with and that
has no non-zero
Hl(C*))
(the two groups of conclusion (4) of Theorem 6 n=l),
(t-divisible part of
Hl(O*)
Therefore, the two subgroups of
Hl(C*)
described in conclu-
sion (5) of Theorem 6 are distinct in this case. This example is also interesting for another reason.
It is
easy to see that
.
Hl (C*) ~
!G, 0,
all integers
iEZ.
i = 1, i
~
1,
However, if
0*
is as in the proof of
Case 4 of Theorem 6, then, by the proof of Case 4 of Theorem 6,
588
Chapter 4 [limj HO(C*/tic*)] ~ [limjHO(o*/tio*)], i>O itO
j=O,l. Also by conclusions (4),
(5) and Note 2 of Theorem 6 (or,
in fact, by conclusion (4) of Theorem 1, since
0*
also obeys
the hypotheses of Theorem 1), we have that [lim itO
l
O H (o*/tio*)]~ (t-divisible part of
But, an explicit computation shows that O-submodule, the
O-module
relations: X
o
N
Hl(O*)
with generators In the
i > 0.
Hl (0*))
O-module
contains, as i ~ 0,
xi' N,
part of
N) c: (t-divisible part of
(where the leftmost isomorphism is the one that sends into
X
o E N).
and
the element
is t-divisible, and is not a t-torsion element.
o ~(t-divisible
.
In fact, Hl (0*)) , 1 E0
In fact, in this case, an explicit computation showl
that Hl(C*/tiC*) =0, [lim itO
all integers
i~O;
and therefore
Hl(C*/tic*)] = 0,
and therefore by the short exact sequence of Corollary 1.2 of Chapter 3,
Therefore, in this case, the epimorphism of conclusion (3') of Theorem 6, for (Note:
is the zero map, and is not an isomorphism.
It is easy to observe directly in this case that for all
i>O, HI (c*/tic*)
....
i = 1,
= 0,
so that
0*
is not necessary in the com-
Cohomology of Cochain Complexes
589
putation).
Notice also that the subgroup
of
in this case is strictly larger than the subgroup,
Hl(C*)
(t-divisible part of
[liml HO(C*/tic*») i>O
Hl(C*».
However, if one uses percohomology,
(see near the end of
Chapter 5 for the definitions), then from the exact sequences of percohomology and the fact that
. I
Hl. (C*) =
i = 1,
G,
0,
all integers
i E;Z,
ill,
it follows that i
= 1,
ill,
all integers
i, j 1
with
j
~
0.
.
Therefore, in this case, 1
[lim HO (C*,O/t1))) "" G"" H (C*), i>O and
[ lim ito
1
HOO (C * , 0/ t i 0 ») = 0.
Therefore, in this case, the natural mappings: i [lim H6(c*,O/t O») ... [lim Hl(C*/tic*)], i>O ito [liml Hg(C*,O/tiO)] .... i>O are not isomorphisms (in fact, both are the zero maps from to zero, and from zero to
G,
respectively).
G
Thus, even in
cases when the epimorphism (3') of Theorem 6 is not an isomorphism, it is still suggested, if one replaces
"H*(c*/tic*)"
by the corresponding percohomology groups (see the end of Chapter 5 for the basic definitions),
"HA(A/tiA,C*)",
then
590
Chapter 4
that the corresponding mapping should be an isomorphism. fact, this is true (if the element
tEA
In
is a non-zero divisor),
see Theorem 6' of Remark 4 below. The remainder of this chapter, Remarks 3 through 8, make use of percohomology, a concept that is defined and studied in Chapter 5 below, following the proof of Corollary 1.2 of Chapter 5.
These Remarks, 3 through 8, involve generalizations and
improvements of Theorem 6, Corollary 1.1, Proposition 2", Corollary 2.1, etc., of this Chapter, and therefore these Remarks belong at this point.
The reader is advised to skip ahead to
Chapter 5, following Corollary 1.2, for the definition of the percohomology groups
H~ (M, C*) ,
complex of left A-modules module
M,
C*
n E;Z,
of ~ (;Z-indexed) cochain
with coefficients in
~
right A-
before reading the rest of this chapter, Remarks 3
through 8 below. Remark 3.
Under the hypotheses of Corollary 6.1, let
any cochain complex of left A-modules. tEA
C*
be
Suppose that the element
is a non-zero divisor, and is in the center of the ring
Then, if the reader uses percohomology as defined in the latter part of Chapter
5 (vide infra), then it is easy to see that for
every integer
n,
that we have a canonical isomorphism:
[lj,m l H~-l(A/tiA,C*))""
(2)
i>O [lim l i~O
(Proof:
Choose
modules and
(precise ti-torsion in 'C*
¢*:' C*
+
a C*
;Z-indexed cochain complex of left Aa map of (.,z-indexed) cochain complexes
of left A-modules such that tegers
n,
Hn(C*))).
n H (¢*)
is an isomorphism, all in-
and such that "multiplication by
tit:
'C n
+
'C n
is
A.
Cohomology of Cochain Complexes injective, all integers
n.
Then the second conclusion of Corol-
lary 6.1 applied to the cochain complex sion (2) of this Remark.)
591
'C*
implies the conclu-
Also, the notations being as in this
Remark, we also have the short exact sequence: O-+Hn(C*)At+ [lim H~(A/tiA,C*)J-;. i>O
(1)
[lim (precise ti-torsion in i>O all integers
n.
Hn + l (C*)) J + 0,
Conclusions (1) and (2) can be interpreted as
a generalization of Theorem 1 of Chapter 2 , in the case that n n "multiplication by t,,:c +C is not necessarily injective for all integers Remark 4.
n - however, this generalization is shallow.
Suppose that the hypotheses of Theorem 6 hold (and t":Cn+C n
that e.g., "multiplication by jective for all integers
n)
is not necessarily in-
and that the element
tEA
non-zero divisor and is in the center of the ring
H~(A/tiA,C*) cients in integers
be the percohomology groups of
n
Then let
with coeffi-
as defined at the end of Chapter ~ below, all
A/tiA i,
C*
A.
is a
with
i > O.
Then one can retrieve all of the
results of Theorems 1 and I', if one uses the percohomology
"H~(A/tiA,C*)",
groups
"Hn(C*/tic*)", Theorem 6'.
"H~-l(A/tiA,C*)"
"Hn-l(C*/tic*)".
Let A
More precisely,
be a ring with identity and let
element of the center of the ring zero divisor.
A,
such that
t
t
be an
is not a
be a (z-indexed) cochain complex of n left A-modules such that C is t-adically complete, all integers
n. (1)
Let
in lieu of
C*
Then For every integer
n,
t-adically complete.
Hn(C*)/(t-divisible elements is Also,
Chapter 4
592
(2')
For every integer
n,
Hn(C*)
has no non-zero in-
finitely t-divisible elements. Also, for every integer
n,
there are induced canonical
isomorphisms of left A-modules: (3)
Hn(C*)/(t-divisible elements) "" Hn(C*)"t""
~!m [H~(A/tiA'C*)). ~>O
Also, for every integer
n,
there are induced canonical
isomorphisms of left A-modules (4)
(t-divisible part of
Hn(C*)) ""
liml [precise ti-torsion in i~O
Hn(C*)) ""
I' 1 HnA-l(A/tiA,C*).
it~
Proof:
By Corollary 3.2 of Chapter 5, there exists a
cochain complex
C*
of the left A-modules, such that
is t-adically complete, all integers
n,
has no non-zero t-torsion, all integers
(~-indexed)
(1)
'C
and such that (2) n,
n
'C
and such that we
have a mapping <j>*:'C*+C* of
(~-indexed)
cochain complexes of left A-modules, such that
is an isomorphism, all integers
n.
Conditions (2) and (3) im-
ply that
all integers
n,
i
with
i > O.
Equations (1) and (2) imply
n
Cohomology of Cochain Complexes that the cochain complex
'C*
of left A-modules obeys the hypo-
theses of Theorem 1 and of Theorem 1'. sions (1),
Therefore we have conclu-
(3) and (4) of Theorem 1 and conclusion (2') of
Theorem I' for the cochain complex us to substitute "Hn-l(,C*)" 'C*,
593
"Hn(C*)"
for
in conclusions (1),
'C*.
Equations (3) allow
"Hn(,C*)"
and
equation (4) allows us to replace and
"H~-l(A/tiA,C*)",
for
(3) and (4) of Theorem 1 for
and in conclusion (2') of Theorem I' for
"H~(A/tiA'C*)",
"Hn-l(C*)"
'C*.
"Hn(('C*)/ti(,c*))"
"Hn-l(('C*)/ti(,c*))"
Finally, with
with
respectively, all integers
i.::O,
sions (3) and (4) of Theorem 1 for the cochain complex
in conclu'C*.
Q.E.D.
Remark 5.
If one has the hypotheses of Theorem 6' of Remark 4,
then one obtains generalizations of Corollary 1.1, Proposition 2, Proposition 2' and Corollary 2.1 when one replaces the "cohomology groups mod till described in these corollaries and propositions with the corresponding "percohomology groups".
The
proofs are entirely analogous to that of Theorem 6' of Remark 4 (and, as in the proof of Theorem 6', immediately reduce to the earlier corollaries and propositions, by constructing ¢*: 'C* + C*
'C*
and
obeying the conclusions of Corollary 3.2 of Chapter
5) •
Corollary 1.1'.
Under the hypotheses of Theorem 6' of Remark 4,
we have that both conclusions of Corollary 1.1 hold (where the generalized Bockstein spectral sequence of the endomorphism "multiplication by
till
C*
with respect to
is as defined in
Remark 4 following Theorem 2 of Chapter 1 in the case that "multiplication by
t":C
n
+c
n
is not one-to-one.)
594
Chapter 4
E~
Thus, for example, Proposition 2'".
=
H~ (A/tiA,C*),
all integers
n.
Under the hypotheses of Theorem 6', let
any fixed integer.
n
be
Then the following seven conditions are
equivalent. (1)
Hn(C*)
is t-adically complete.
(2)
Hn(C*)
has no non-zero t-divisible elements.
(3)
The natural mapping: n H (C*)
H~ (A/tiA, C*)
lim i>O A-modules:(4)
(a)
->-
uEHn(C*),
If
then and
(b)
u
then
u
t-u=O,
and
u
is t-divisible,
is infinitely t-divisible
n u E H (C*)
If
is an isomorphism of left
and
t
i
- u"l 0,
all integers
i,
is not t-divisible.
(4') Every t-divisible element in
Hn(C*)
is infinitely
t-divisible.
(5) (6)
Proof:
liml (precise ti-torsion in i~O l~ml Hn - l (A/tiA,C*) = O. A i>O Take
n H (C*) ) = O.
as in the proof of Theorem 6'.
'C*
tion 2 and Proposition 2' for
'C*
Then Proposi-
imply Proposition 2 "'
C*.
for Q.E.D.
And similarly Corollary 2.1 immediately generalizes: Corollary 2.1'. let
n
Under the hypotheses of Theorem 6' of Remark 4,
be an integer such that the seven equivalent conditions
of Proposition 2'"
all hold.
Corollary 1.1', we have that (1)
liml i>O
E~(ti)
=0.
Then, the notations being as in
Cohomology of Cochain Complexes
595
And Remark 1 following Corollary 2.1 similarly generalizes. Remark 6.
An amusing consequence of Theorem 6, Note 2, is that,
under the hypctheses of Theorem 6, if n 1m (d : C n
that
-+-
n l C + )
n
is any integer such
has no non-zero t-torsion, and if
n u E H (C*) ,
then
u
is t-divisible in
Hn(C*)
iff, for every non-negative
n there exists v. E H (C* / (precise ti-torsion)), integer i, l. such that the image of V. under the mapping induced by multil. plication by
is
ti:
u.
Proof:
From the long exact sequence of cohomology of the short
exact sequence of cochain complexes: .
uti"
.
0-+ [C*/ (precise tl.-torsion)] ~C* -+ C*/tl.C* we see that there exists Hn(C*/tic*) gers
i> 0
is zero.
vi
0,
as above iff the image of
Thus, there exist such
iff the image of
-+
u
in
vi
u
in
for all inte-
lim [Hn(C*/tic*)]
is zero.
itO But, by conclusion (3') of Theorem 6 and Note 2, this latter occurs iff Remark 7.
u
Q.E.D.
is t-divisible.
In Remark 3, Theorem 6' of Remark 4, Corollary 1.1'
of Remark 5, Corollary 2.1' of Remark 5, Proposition 2"1 of Remark 5, but not in Remark 6 - in fact, throughout most of the last Remarks - we had to assume that the element zero divisor.
tEA
is a non-
This assumption can be removed, and the entirety
of these Remarks then remain valid, if throuahout, we replace
596
Chapter 4
the percohomology groups
"H~ (A/tiA, C*) ", Here
C*
(where
etc., by
is regarded as being a cochain complex of Z[Tj-modules is the polynomial ring in one variable over
Z [T]
by requiring that center of
"T"
acts as
C*
the action of
"T"
then since "T"
(Then, if
t
is in the
is a cochain complex of left A-modules, and (=
the action of
action of every element of
since
"t".
Z)
H~[T] (C*,Z [T]/TiZ[T]), etc., is also a left A-
A,
module since
A,
"H; (T] (C* ,Z (T] /TiZ [T] ) ", etc.
and
A.
"t")
Also, if
commutes with the t
is in the center of
i "T "
acts as zero in
Z[T]/(T
"t"
act the same on
C*, it follows that the
left A-modules, e.g.
H~(A/tiA,C*)
and
i
'Z[T]),
and
H;[T] (C*,;Z[TJ/TiZ[T]),
i
are actually left (A/t A)-modules.) Remark 8.
One might wonder, under the hypotheses of e.g., Theo-
rem 1, if
n
Hn(C*)
is a fixed integer, whether it is possible for
to possess t-divisible elements; and, if so, whether or
not the t-divisible part of
Hn(C*)
(which by conclusion (2')
of Theorem 6 has no infinitely t-divisible elements) must necessarily be, either a t-torsion module, or else be free of nonzero t-torsion?
The following two examples (of a rather practical
nature from our p-adic cohomology in algebraic geometry) show that all such questions are answered in the negative; otherwise stated, in "practical" examples, pathologies "just as bad as looks conceivably possible" can occur under the hypotheses of, e.g. Theorem 1. Example 1.
Let
A= 0
be a complete discrete val ua tion ring of
mixed characteristic, let
r
be a positive integer and let
Cohomology of Cochain Complexes
597
H=O[T , ... , T }, the polynomial ring in r variables over O. l r n Let B = the n' th exterior power of the module of differentials of the
O-algebra
O-modules. O.
Then
Let
t
Then
B*
is a cochain complex of
be any generator for the maximal ideal of
H"t = ring of t-adically convergent power series over
in r-variables. n> r resp.
H.
Let or
C* = (B*)At.
(Then is is easy to see that
i < 0,
n
and
B , resp.
n .~s a f ree C,
H";-module of finite rank, all integers
n.
However, of
are not finitely generated as
course
O-modules,
and of course the coboundaries are not H-linear in either or
H,
B*
C*). It is easy to see (see Examples in Remark 1 of Chapter II
of [p.p.we.}) that Hn (B*) "" ED (O/tiO) i>l
(1)
all integers n H (C*),
n
(w) ,
1 < n < r.
such that
The cohomology
l
is much more pathological, even though plete and "multiplication by tegers
n
t":
cn
C*
+C n
is t-adically comis injective, all in-
(i.e., the hypotheses of Theorem 1 hold).
In fact,
each of the six equivalent conditions of Proposition 2 all fail n H (C*), all integers
for
n
such that
1 < n < r.
dition of Corollary 2.1 holds for all integers
E~(ti) =0,
fact
all integers
i EO (t ) = O/tiO , all integers 00 using C*
B*
instead of
C*
i >
i2:,0,
n,
(But the consince in
all integers
° - this
nlO,
and
computation follows by
(the two cochain complexes
B*
and
have the same generalized Bockstein spectral sequences for
0
598
Chapter 4 all integers
the endomorphism same
E~(ti)),
i ~ 0,
since they have the
using Theorem 2 of Chapter 1, and equation (1)
of this Example).
In an Example in a Remark in Chapter II of
[P.P.WCJ, I noted that
Hn(C*)/(t-divisible elements) has non-
trivial topological t-torsion, so that n [H (C*) / (divisible elements)] ® K
o
is an uncountable dimensional K-vector space, all integers such that
1 < n
(when
K
is the quotient field of
n
0).
As an application of Proposition 5, we show that the tdivisible part of tion of a free
Hn(C*)
for
l::'n::'r,
is the t-adic comple-
O-module of uncountably infinite rank.
(Which
of course implies that condition (1), and therefore all the equivalent conditions (1), (2), ... , (6) of Proposition 2 fail for C*, as we asserted above). In fact by the second conclusion of Corollary 6.1 applied to the cochain complex (2)
B*,
we have that for every integer
(t-divisible part of [lj,m
l
n
Hn(C*)) ""
(precise ti-torsion O'f
Hn(B*))]
i>O
(Since by definition But, if
C*
=
(B*)").
n M = H (B*), then by equation (1) of this Example,
M
has no non-zero t-divisible elements, and therefore obeys the hypotheses of Proposition 5. (3 )
' 1 [1 ~m i>O
(
Therefore, by Proposition 5,
, , , preClse t i -torslon In
[lim (precise ti-torsion in i>O The
M)] ""
M"/M)].
O-module on the right side of equation (3) is clearly
Cohomology of Cochain Complexes
599
the t-adic completion of a free
a-module of rank equal to the
dimension of the k-vector space:
(precise t-torsion part of rf /M)
where
k=a/tO.
But, if
easy to see that k-vector space.
rf/M
l:::n.:.r,
then from equation
(1)
it is
is of uncountably infinite dimension as
(Proof:
If
u.
is one of the basis elements
1
in the i'th direct summand of the right side of equation (1), all integers
i .:::. 1,
w (a i) i> 1 E k ,
then for every sequence
we
have the distinct t-torsion elements: \,'
La. (t.
i>l
in
1\
The images of these elements in
M.
of cardinality:
(cardinal (k»
cise t-torsion part of space,
i-I
1
~
It follows that the k-vector
(precise t-torsion part of
finite dimension}.
are a subset
of the k-vector space (pre-
0
rf/M).
rf /M
MA/M), is of uncountably in-
Combining this observation with equations
(2) and (3), we see that (t-divisible part of t-adic completion of a free
Hn(C*»
~ (the
a-module of uncountably infinite
rank) . Remark.
Notice that, under the hypotheses of Theorem 1, the
conclusions of Corollary 2.1 may hold, sometimes even when the conclusions of Proposition 2 fail.
E.g., see the preceding
Example. Example 2.
Let
A
be a ring with identity and let
Assume for simplicity that M be any left A-module.
t
is a non-zero divisor in
all integers
A.
Then choose an A-homomorphism
of free left A-modules such that Bn=O,
tEA.
nt-O,l.
M~
Then
a
Coker (d ) I B*
and define
is a cochain complex
Let
I
Chapter 4
600
of left A-modules and
Hl(B*) '" M.
Define
C* = (B*)J\t.
Then the
hypotheses of both parts of Corollary 6.1 are satisfied, so that by conclusions (1) and (2) of Corollary 6.1 we have that (1)
(t-divisible part of
Hl (C*))'"
liml (precise ti-torsion in
M).
i>O
But, by Theorem 4, we have a monomorphism:
(2)
~
(t-divisible part of M) (infinitely t-divisible part of liml (precise ti-torsion in
M)
M).
i>O
Combining equations (1) and (2), we see that if A-module, e.g. such that
M is any left
M has no non-zero infinitely t-divi-
sible elements, then the (t-divisible part of isomorphic to an abelian subgroup (or if of A,
to a left A-submodule) of (3)
Here
(t-divisible part of
t
M)
is canonically
is in the center
Hl(C*), M)
C
Hl (C*).
C* is a (non-negatively indexed)cochain complex of left
A-modules that obeys all the hypotheses of Theorem 1.
Equation
(3) above shows, under the hypotheses of Theorem 1, just how "bad" the divisible part of left A-module
M,
we can build a
of Theorem 1, such that t
Hn(C*)
is in the center of
Hl(C*) A,
can be - namely, for every C*
obeying all the hypotheses
contains, as a subgroup (of if
as a left A-submodule) the group
(or left A-module) (t-divisible part of M) (infinitely t-divisible part of
M)
.
Cohomology of Cochain Complexes (Of course, by conclusion (2') of Theorem 6,
601
Hn(C*)
has no
infinitely t-divisible elements; so that in essence this last counterexample
cannot be improved upon).
Thus, in particular, we have examples of hypotheses of Theorem 1, such that Hn(C*)
C*
obeying the
has e.g. t-divisible,
t-torsion elements that are not infinitely t-divisible. Let
A
be a ring with identity and let
divisor in the center of the ring
A.
t
Then if
be a non-zero C*
is any (z-
indexed) cochain complex of left A-modules, such that (multiplication by
t): c
n
->-c
n
is injective, all integers
n,
then the
natural mapping induced on percohomology:
is an isomorphism, all integers Since
t
c
with
i >
is a non-zero divisor in the ring
(mutliplication by 1.1.1,
n, i
nAt
->-
c
nAt
,
t): c
n
n ->- C ,
o.
A,
(Proof: and since
and therefore also by Lemma
is injective, all integers
n,
we have
that
all integers
n, i
from the fact that e*/tie*.)
with
i > O.
e*At/tic*At
is canonically isomorphic to
Does this result remain true if one deletes the hypo-
thesis that "multiplication by integers
So the indicated result follows
n?
The answer is
discrete valuation ring and t A, and even if
C*
t":
en ->- en
is injective, all
"no", not even if
A
is a complete
generates the maximal ideal of
is non-negative and
en
=
0
for
n;: 3,
and
602
Chapter 4 is finitely generated as A-module, all integers
n,
as
is seen by Example 3, below. Also, if
A
is a ring with identity and if
ment in the center of the ring
A
t
is an ele-
that is a non-zero divisor,
then let (1)
'c* ->c*
be a map of (z-indexed) cochain complexes of left A-modules such that the endomorphism;;;, "multiplication by t", of the left An n modules 'C and c , are injective, all integers n. Then if ¢*
induces an isomorphism on cohomology in all dimensions, then
so does
(Proof:
lS
By Theorem 6' of Remark 4, it suffices to prove that
an isomorphism, all integers
n,
i
with
i > 1.
But by the
observation of the preceding paragraph, it is equivalent to show that
is an isomorphism, all integers
i, n
with
i >
o.
But this
latter observation follows from the universal coefficients spectral sequence of percohomology.) One might ask that, if one deletes the hypotheses on and
I
C*,
that "multiplication by
are injective, all integers
n,
til,
en
-+
en,
and
I
en
C* -+
then does it remain true if
I
cn ¢*
Cohomology of Cochain Complexes
603
is a mapping of cochain complexes as in equation (1) that induces an isomorphism on cohomology in all dimensions, then is it necessarily true that the mapping
¢*At
in equation (2)
necessarily induces an isomorphism on cohomology? "no", not even if
A
is a complete discrete valuation ring,
is a generator for the maximal ideal of n C
both non-negative, tion n,
Hn(C*)
The answer is
=
'C
n
=
°
for
A,
n> 3
C*
and
'C*
t
are
and even if in addi-
is finitely generated as an A-module, all integers
as seen in Example 3 below.
Example 3. a field
Let
A=
(e.g., 0
be a complete discrete valuation ring not
=£, p
p
O.
Let
quotient field of ideal of
a
any rational prime). t
Let
K
be the
be a generator for the maximal
O.
Then let
I
n = 1,2,
Kia,
Cn =
0,
nr!1,2,
and let
d
Then
n
multiplication by
=
( 0, is a
We have that
Let
,cn
=
= 0,1
0,
n
0,
nr!O,l
j
n = 1 n r! 1.
n n C* = (C ,d )nEZ
A-modules.
t,
(non-negative) cochain complex of left
Chapter 4
604
and
'd
n
n=O
t,
multiPlication by =
\ 0,
n
10.
Then
is a
(non-negative) cochain complex of left A-modules, and
'c*"t
= 'C*.
Let
be the unique homomorphism of A-modules that maps the class of
CP*:
1
t'
Let
lEO
into
Then
'C*+C*
is a map of cochain complexes of left A-modules that induces an isomorphism on cohomology in all dimensions.
Notice that
n=l
nIl, all integers
n.
Notice also that
all integers
n.
Therefore
percohomology of
C*
'C*
'Cn
.
H~ (C* ,A/t1A)
0,
with coefficients in any A-module.
=
{A/tA, 0,
for
can be used to compute the
this way, we see that, e.g.,
(1)
is flat over
n = 0,1 n 10,1,
In
Cohomology of Cochain Complexes all integers
n, i
with
i
~
1,
605
and that the natural mappings:
an isomorphism if
n = 1,
the zero map
n=O,
are
for
n = 0, 1.
Therefore
(2)
H~(C*,A/tiA)
lim i>O
all integers (3)
n,
if
--1 A/tA,
n
= 1,
0,
n
t
and
liml HAn (C*,A/tiA) = 0, i>O
all integers
n.
On the other hand, since replace
1,
C*
with
c*/\
C*/\=O,
it follows that, if we
on the left sides of equations (1), (2),
and (3), then the right sides become zero. Therefore, for this cochain complex
C*,
the natural
map:
H~ (C* ,A/tA) .... H! (c*/\, A/tA) is not an isomorphism.
Also, although the map of (z-indexed)
cochain complexes of left A-modules ¢*:
'C* .... C*
induces an isomorphism on cohomology, nevertheless the induced map of
(Z-indexed) cochain complexes on the completions
606
Chapter 4
does not induce an isomorphism on cohomology (since
HI ('C*At) =HI ('C*) "" A/tA,
but
HI (C*At) = HI = 0).
(the zero cochain complex)
CHAPTER 5 FINITE GENERATION OF THE COHOMOLOGY OF COCHAIN COMPLEXES OF t-ADICALLY COMPLETE LEFT A-MODULES
Proposition O.
Let
A
be a ring with identity and let
an element of the center of the ring
A.
complex of the left A-modules such that plete, all integers (0)
i,
(multiplication by
nand
r
ci
C*
be
be a cochain
is t-adically com-
and such that
all integers Let
Let
t
ci
t):
-+
ci
is injective,
i.
be fixed integers with
r > O.
Then the
following conditions are equivalent: is the image of some t-torsion ele-
(1)
ment in
Hn(C*),
then
u
tr-torsion element in (2)
n u E H (C*),
t i . u = 0
H
n
is the image of some precise (C*).
for some
i
~
0,
implies that
tr·u=O. (3)
If
then (4)
u E Hn - l (C* /tC*) dn-l(u)
is such that
is t-divisible in
d n - l (u) E t r • Hn (C*) , Hn(C*).
n If u E H (C*) is a precise t-torsion element such r that u=t ·v, for some vEHn(C*), then u is t-divisible.
(5)
In the (singly graded, cohomological) generalized Bockstein spectral sequence, as defined before Lemma 1 607
608
Chapter 5 of Chapter I, we have that d
n-l r
=d
(6)
n-l = r+l
Let
=d
n-l =0, s
n u E H (C*)
all integers
s>r.
be any t-torsion element.
Then the
following four conditions are equivalent: exists
n v ~ H (C*)
finitely t-divisible; proof:
u =t
such that u
r
. v;
u u
there
0;
=
is in-
is t-divisible.
By conclusion (2) of Theorem 1 of Chapter 4, we have
that there are no non-zero infinitely t-divisible, t-torsion elements in
o
Hn(C*).
Therefore, condition (2) of Proposition
is equivalent to, e.g., condition (5') of Corollary 3.1 of
Chapter 1.
And also, for the same reason, condition (6) of the
Proposition is equivalent to condition (5) of Proposition 3 of Chapter 1.
In addition, condi tions (1), respectively:
(3), (4)
I
(5) of Proposition 0 are identical to conditions (2), respectively: (3), (4),
(1) of Proposition 3 of Chapter 1.
equivalence of conditions (1), (3), (4), (5) and
o
Therefore the (6) of Proposition
follows from Proposition 3 of Chapter 1; and the equivalence
of condition (2) of Proposition 0 with the other five conditions follows from Corollary 3.1 of Chapter 1. Lemma 1.1.1.
Let
A
Q.E.D.
be a ring with identity and let
element in the center of the ring is t-adically complete.
A.
t
be an
Suppose that the ring
Then the following two conditions are
equivalent. (1)
A
(2)
The ring
Proof:
is left Noetherian
(1)~(2)
Suppose that
AltA
is left Noetherian.
is obvious. AltA
To prove that
is left Noetherian.
(2)~(1).
Then let
I
be
A
Finite Generation any left ideal in the ring
A.
609
For each integer
n,::, 0,
define
of left ideals by inHaving defined
duction as follows. n.::. 0,
let
In+l = {x E A: tx E In}'
I=IOc1lc12c ... c1nc", in the ring
AltA
r >0
ideal
I
in the ring
Therefore there exists an in-
left ideal
Then
I
ul, ... ,u
A
is finitely generated by induction on
1=1 =1 =
o
generate I
m let
x EI
elements
a , ... , am E A l
But then
xl E II'
,aIm E A
But then
x
a.l, ... ,a. J
But then
Jm
2
Ul
Let
n
' ... ,
urn E I
Since
be any element. and an element
II = I,
AltA.
Then I claim A.
Then there exist xl E A
x2 E A
j
x. E I. ]
the
such that
there exist elements
By induction on
and elements
generate
as left ideal in the ring
and an element
E1 , 2
EA
=1
1
in the left Noetherian ring
In fact,
all""
We prove that the left
Ir = Ir+l = ...
be elements such that the images
that
I ,I l ,I 2 , ... ,I n , ... O
r.
r = O.
Case I.
Then the sequence
of images of
AltA.
such that
the integer
for some integer
n
is an ascending sequence of left ideals in
the left Noetherian ring teger
I
J
such that
~
1,
we construct elements
such that
610
Chapter 5 x = (a l + (,Lltjajl) )u + (a + ( L tja '2) )u l 2 2 h j~l ] + ... +(a
m
+
Itja,)u Jm m
,L
J~ l
in the t-adically complete ring generated the left ideal Case II. II c A
r> 1.
is
II
I
"r"
for the left ideal
so that by the inductive assumption, there
exists a finite sequence
the ideal
as asserted.
Then the integer
r-l,
that generate
I,
Therefore
A.
vI""
,v
k
E II
of elements of
as left ideal in the ring
in the left Noetherian ring
generated, there exists an integer
AltA
m> 0
tvl, ... ,tv fact,
let
k
x E I.
I
Then since
ideal in the ring
EI
generate
generate
xl E A
I
generate
as left
a , ... ,am E I l
A.
generate b , ... , b
l
k
EA
in Equations (1) and (2)
I
In
such that
there exist elements
as left ideal in
such that A.
imply that
completing the proof that as left ideal.
as left ideal.
AltA, there exist elements
Since
I
I
u ' ... , urn l
in
A,
is finitely
We claim that the elements
of the ideal
and an element
Since also
and elements
such that the images as Ie ft idea 1.
A.
II
u ' ... , urn' l
tv l' ••. , tv k E I
generate
Q.E.D.
Finite Generation
611
The main theorem is Theorem 1. center of
Let A.
A
be a ring and let
Suppose that
A
t
be an element in the
is t-adically complete.
be a cochain complex of left A-modules,
Let
C*
indexed by all the in-
tegers, such that
gers
(1)
m C
(2)
(multiplication by
m.
is t-adically complete, all integers
Let
n
t) :C
m
m ..,. C
be any fixed integer.
m,
and
is injective, all inteThen if
is finitely generated as left A/tA-module, and if the ring
A
is left Noetherian, then is finitely generated as left A-module.
Also, when this is the case, there exists an integer that the six equivalent conditions of Proposition fixed integer (2)
n,
such that
Remark.
a
such
hold for the
and in particular
There exists a fixed integer
that
a
r>
uEHn(C*),
tiu=o
r >0
(depending on
for some
i~O,
n)
implies
tru = O.
Clearly, if the ring
A
is left Noetherian, then con-
clusion (1) of Theorem 1 implies conclusion (2) of Theorem 1. Corollary 1.1.
Under the hypotheses of Proposition 0, let
an integer such that there exists an integer
r >0
six equivalent conditions of Proposition 0 hold.
n
such that the Then also
is t-adically complete, and the natural homomorphism is an isomorphism (1)
Hn(C*) ':';.lim Hn(C*/tic*).
i>O
be
Chapter 5
612 In addition
liml Hn - l (C*/tiC*) = O. i> 0
(2)
Corollary 1.2.
m i Em (t ),
mE:z,
The hypotheses being as in Corollary 1.1, let be the
E",,-term of the generalized Bockstein
spectral sequence, as defined in Theorem 2 of Chapter 1 for the cochain complex
C*
and the endomorphism "multiplication by
Then for the fixed integer (1)
tin.
n
Hn(C*)/(t-torsion)~ lim E~(ti), i>O
and (2)
liml En - l (t i ) = i> 0
o.
Proof of Theorem 1 and of Corollary 1.1:
By Proposition 3 of
Chapter 1 and Corollary 3.1 or Corollary 3.2 of Chapter 1, the condition
(*n)'
and the fact that the ring
A
is left Noether-
ian, imply that the six equivalent conditions of Proposition 0 above hold, for some integer r > 0,
r >
o.
(The boundaries,
being an ascending sequence of
n E~ = H (C* /tC*) , of Theorem 1.
must stabilize).
(A/tA) -submodules of
This proves the last sentence
Assume now that we have the hypotheses of Corollarl
1.1.
Consider condition (5) of Proposition 2 of Chapter 4 (IV. 2. 5) By condition (2) of Proposition 0 above, if we let be the inverse system in (IV.2.5), then in
Hn(C*)),
i.::.r,
and the map
,a .. ). '>0 1J 1,J_ A. = (precise tr-torsion (A.
1
1
ai+j,i=(mulitiplicationb Y
Finite Generation t
j
)
=0
whenever
j
~ r,
i > O.
613
Therefore
" A, = I'*m 1 A, = 0 , I ~m
i>O
i>O
l
l
so that condition (IV.2.5) above holds. ditions Hn(C*)
of Proposition 2 of Chapter
Therefore all the con-
4 hold.
is t-adically complete (condition
of Chapter
In particular,
(1) of Proposition 2
4), and conclusions (1) and (2) of Corollary 1.1
above follow from cor.ditions
(3) and (6), respectively, of
proposition 2 of Chapter 4
This proves Corollary 1.1.
It re-
mains to verify conclusion (1) of Theorem 1, under the strong assumption (*n)' (4)
In fact,
Hn(C*)
is a t-adically complete left A-module
(by Corollary 1.1), and the long exact sequence of cohomology: n-l d_ _"H n (C*) ..!.>H n (C*) implies that
Hn(C*)/tHn(C*)
-+
n Hn (C*/tC*) ~ ...
is isomorphic as
(A/tA)-module
to a submodule of the finitely generated (A/tA)-module Since by hypothesis the ring
A/tA
Hn(C*/tC*).
is left Noetherian, it
follows that (5)
n (A/tA) ® H (C*)
is finitely generated as (A/tA) -module.
A
Conditions (4) and (5) the left A-module In fact, let and
M/tM
is finitely generated.
n M = H (C*) .
Then
is finitely generated as
e , ... ,e E M l h M/tM
Hn(C*)
(on any A-module) easily imply that
be such that the images
as (A/tA)-module.
Then
M
is a complete A-module
(A/tA)-module.
Let
el , ... ,eh E M/tM
el, ... ,e h
generate
generate
M as
614
Chapter 5 (Proof:
A-module.
If
x E M,
x =: aIel + •.• + ahe h (mod tM) , By
inductio~
Xi E M,
i
~
integers
there exist
0,
such that
i > 1.
so that
x
a
(i)
l
then 3 a , ... , a E A such that h l say X = a e + ••. + ahe + tx . h l l l (i)
, ... , ~ (i)
xi = a l
E A,
l
~
(i)
e l + .•• + a h
0,
and all
e h + tx i + l ,
Then
is in the A-submodule of
M generated by Q.E.D.
e , .•. , e ) . l
h
Remarks.
1.
Let
A
be a ring with identity and let
an element in the center of the ring
A.
tEA
be
Suppose also that the
several equivalent conditions of Proposition 0, or of Corollary 3.1 of Chapter 1, hold (equivalently, that conclusion (2) of Theorem 1 holds).
(It suffices, e.g., that
A
ian and that the image of the natural mapping:
be left NoetherHn(C*) -T Hn(C*/tC*
be finitely generated as (A/tA)-module; or weaker that
A
be not
necessarily left Noetherian, and that the image of the t-torsion under the natural mapping: genera ted as
Hn(C*) -THn(C*/tC*)
be finitely
(A/tA)-module (since then
ously stabilizes)).
obvi-
r ~ 0,
Then the proof of Theorem 1 above shows
that the following two conditions are equivalent: (1)
Hn(C*)
(2)
the image under the natural homomorphism
is finitely generated as an A-module, and
Hn(C*) -THn(C*/tc*)
is finitely generated as
(A/tA) -module. 2. (*), n
Suppose that the hypotheses of Theorem 1, except hold, and that
A
is left Noetherian.
Let
n
possibl~
be a fixed
Finite Generation integer.
615
Then the following two conditions are equivalent:
(1)
Hn(C*)
is finitely generated as left A-module.
(2)
The image under the natural mapping: n
n
p :H (C*) .... H (C*/tC*)
is finitely generated as A-module. Proof:
(1)
since
(A/tA)
image of
p
~
(2)
is obvious.
Conversely, assume (2).
is Noetherian, every
Then
(A/tA)-submodule of the
is finitely generated as
particular the image of the restriction
(A/tA)-module, and in T
of the natural map
p,
T:{t-torsion in
Hn(C*)} .... Hn(C*/tC*).
But (Chapter 1, Corollary 1.1) the image of
T
is
Boo (E~)
in
the generalized Bockstein spectral sequence (for the cochain complex
C*
and the endomorphism "multiplication by is finitely generated as
fore
fore there exists an integer
r
t").
There-
(A/tAl-module, and there-
such that
Therefore the conditions of Proposition 3 of Chapter 1 hold, so that by Remark 1 above,
Hn(C*)
is finitely generated as
A-module.
Q.E.D.
Proof of Corollary 1.2: Chapter 4 ter
In fact, the hypotheses of Theorem 1 of
hold, so by conclusion (1) of Corollary 2.1 of Chap-
4, we have conclusion (2) of the Corollary.
lary 1.1 of Chapter
Also, by Corol-
4, we have the canonical isomorphism of
A-modules (3)
[Hn(C*)/(topological t-torsion) 1'" lim
i>O
E~(ti).
Chapter 5
616
To complete the proof of conclusion (1) of this Corollary, it therefore suffices to show that (4)
{topological t-torsion in {t-torsion in
Hn(C*)}
=
Hn(C*)}.
But in fact, by conclusion (2) of proposition 0, (5)
n H (C*) } =
{t-torsion in
{precise tr-torsion in for some positive integer Corollary 1.1,
Hn(C*)
t-adically Hausdorff,
r
Hn(C*)}
(depeding on
n).
But since by
is t-adically complete, and therefore {precise tr-torsion in
Hn(C*)},
being
the kernel of the (continuous) homomorphism of Hausdorff topological groups,
(multiplication by
r t ): Hn(C*) +Hn(C*},
it
follows that (6)
{precise tr-torsion in in
Hn(C*).
Equations (5) and (6) imply that t-adically closed in t-torsion")
Hn(C*)} is t-adically closed
Hn(C*),
{t-torsion in
Hn(C*)}
is
and (by definition of "topological
this implies equation (4), and therefore the Corol-
lary. Can Theorem 1 be generalized to cochain complexes of A-modules that are t-adically complete, but such that the endomorphism, "multiplication by
t"
is not injective?
TheDefini-
tion and Proposition that follows, about percohomologx grouvs, answer
th~s
question in the affirmative.
First, let us introduce some terminology.
A
(~-indexed)
Finite Generation cochain complex spectively: i that e = 0
C*
617
of right A-modules is bounded below, re-
bounded above, iff there exists an integer whenever
cochain complex
C*
i
< N,
respectively:
i > N.
n.
The cochain complex
extremely right flat iff there exists a directed set (ei,aij)i,jEI
such
A (.?"-indexed)
will be called right flat iff every
right flat, for all integers
direct system
N
en
C*
is and a
I
of right flat cochain complexes
of right A-modules, such that each of the cochain complexes is bounded above, for all e* "" lim
HI
is
i E I,
C~
].
and such that
C~
].
as cochain complexes of right A-modules.
Thus, every extremely
right flat cochain complex is right flat: but as we shall see (Example 2 below), the converse is in general false. Definition.
Let
A
be a ring with identity, let
e*
be an
arbitrary (Z-indexed) cochain complex of right A-modules and let
M be any left A-module.
groups of e* n H (e* ,M) ,
with coefficients in
n E Z,
as follows.
Then we define the percohomology M,
which we denote as
or sometimes more precisely
H~ (e* ,M) ,
n E Z,
We give three definitions (Definition 1, Definition
2, and Definition 3) which we prove below yield canonically isomorphic groups (and independent, up to canonical isomorphisms, of any choices made in these definitions). Definition 1.
Let
'e*
be another (Z-indexed) cochain complex
of right A-modules such that the cochain complex
IC*
i5 cx-
tremely right flat, and such that we have a map of cochain complexes
618
Chapter 5 CP*:'C*->C*
such that 'C*
Hn(CP*) is an isomorphism, all integers
(Such a
always exists - e.g., use a double complex that is a projec·
tive resolution of let
n.
'C*
C*, in the sense of [C.E.H.A.], pCJ.363, then
be the associated singly graded cochain complex). (*)
(It is easy to see that below, even if
C*
'C*
may of necessity not be bounded
is non-negative.) n
H~(C*,M) =H ('C*3M),
(1)
Then define
all integers
n.
A
Definition 2. M.
Define
Let
Dn=P
-n
P* ,
be a flat resolution of the left A-module all integers
n
(thus, the cochain comple)
D* is non-positive), and define (2)
n
H~(C*,M) =H (C*I3D*),
all integers
n.
(**)
A
Definition 3.
Choose
is an isomorphism, nit ion 2.
'C*
n c"if,
and
cjJ*: 'C* ->C*
and choose
P*
such that and
D*
Hn(CP*)
as in Defi-
Then define
H~(C*,M) =H n ('C*3D*), A
all integers
n. (*** )
(*) This construction appears in the (lengthy) footnote to Remark 4 following Theorem 2 of Chapter 1, construction number (1) •
(**) Notice that Definition 2 generalizes the one presented,construction (2),in the footnote to Remark 4 following Theorem 2 of Chapter 1. (***) Notice that Definition 3 generalizes the one presented, construction (3), in the footnote to Remark 4 following Theorem 2 of Chapter 1.
Finite Generation
619
Then, by methods similar to those used in the footnote to Remark 4 following Theorem 2 of Chapter 1, it is easy to show
H~(C*,M)
that the above three definitions of
give canonically
isomorphic definitions, and are independent of all choices. Proof:
We first prove a lemma.
Lemma A. Let
A
be a ring with identity, let
R*
be a
dexed) cochain complex of right A-modules and let
(Z-in-
p*: S* .. T*
be
a mapping of (Z-indexed) cochain complexes of left A-modules. Suppose that (1)
Rn
is flat as right A-module, all integers
n,
and
that (2)
Hn(P*): Hn(S*) -+Hn(T*) gers
also
(3)
(4)
n.
Suppose
that either and
is an isomorphism, all inte-
T*
R*
is bounded above; or that both
are bounded below.
S*
Then
Hn(R* ~ p*): Hn(R* ~S*) ->Hn(R* ~T*) A A A is an isomorphism of abelian groups, all integers
~.
If we delete hypothesis (3), but instead strengthen hypo-
thesis (1) to read: (lxtr)
R*
is extremely flat,
then again conclusion (4) of the Lemma holds. Proof. Case 1.
In addition,
S*
and
T*
Then there exists a positive integer for Sn
n.
n > N + 1;
= Tn = 0
for
and such that either n < -N - 1.'
are both bounded above. N n R
such that
=0
for
Sn = Tn = 0
n ~N + 1;
or
620
Chapter 5 Then
R* 13 S*
and
A
groups. R*
(9
R* 13 T*
are double complexes of abelian
A
The first spectral sequence of the double complex:
S*
is such that
A
EP,q = R P 13 sq o A'
dP,q=RP@d q o A S*'
all integers
p,qE?'.
(E.g., see Introduction, Chapter 2, section 10.
Or [P.P.W.C.],
Chapter I). RP
Since
(5)
is flat as right A-module, it follows that q Ei' q "" RP 13 H (S *), A
all
p, q E l' •
Similarly, the first spectral sequence of the double complex of abelian groups
R*
(9
T*
is such that
A (6 )
EP,q ~ RP 13 Hq (T*) , 1 ~
all
p,qEl'.
A
The cohomological, doubly graded spectral sequences (5) are confined to the region: -N.::.q'::'+N,
p,q '::'N,
and have for abutments:
and (6)
or to the region Hn(R*(>:lS*),
nE?',
and
A
Hn(R* @T*),
n EU',
respectively.
Since the indicated regions
A
are such that, for every (p,q)
on the line
n,
p + q =n
there are only finitely many such that
it follows
(see Introduction, Chapter 2, section 10) that the filtrations on these abutments are finite.
p~
induces a mapping from the
spectral sequence (5) into the spectral sequence (6).
By hypo-
thesis (2) of the Lemma, and by equations (5) and (6), the map induced by
p*
betweeen these two spectral sequences induces
an isomorphism along
and therefore along the abutments,
completing the proof of Case 1.
Finite Generation
Case 2. and
General Case.
T*(N)
621
For each integer
N
let
be the sub-cochain complexes of S*
S*(N), and
T*,
re-
spectively, such that
n'::'N - I, n = N, n~N+l,
n'::'N - I, n = N,
n>N+l. Then the restriction
p*(N)
of
p*
to
S*(N)
is a mapping
of Z-indexed cochain complexes of left A-modules from into
T*(N),
and the cochain complexes:
and the map of cochain complexes:
R*, S* (N),
p*(N)
S*(N) T* {N)
obey the hypotheses
(I), (2) and (3) of the Lemma, and also obey the hypotheses of Case I, for all integers
N.
Therefore, by Case I, we have that the
homomorphism of abelian groups n n H (R* 0 p* (N) ): H (R* ~ S* (N» A A is an isomorphism, all integers limit in equations (4 ) N
as
N -+ +
n. 00
-+
n H (R* 0 T* (N) ) A
Passing to the direct we obtain that the homomor-
phism (4) is an isomorphism, all integers
n,
(since both coho-
mology of cochain complexes of abelian groups, and tensor products, commute with direct limits over directed sets), which proves Case 2. Proof of Note.
Let
I
be a directed set and
(R~,ao 0) 0 ~
~J
0EI
~,J
a direct system of right flat cochain complexes, each bounded above, such that
R* '" lim Rr •
iEr
~
622
Chapter 5
Then for every
Ri'
i t= I,
hypotheses of the Lemma.
8*,
T*
and
iEI
T*
-+
obey the
Therefore
is an isomorphism, for all integers limit for
p* :8*
n.
Passing to the direct
in equations (4 ), we obtain equation (4). i Q.E.D.
Remark:
If we simply delete hypothesis (3) of Lemma A, then
the Proof of Case 1 of Lemma A, together with Prop. 4 of Introduction, Chapter 2, section 8, shows that the induced mapping of cochain complexes of abelian groups: q ([
(RPOS )]
•
p+q=n
A
•
P2.0
[
IT
(R
p+q=n p>O
P
0 sQ) ] )
---i>
A
nE~
induces an isomorphism on cohomology in dimension integers
n.
n,
for all
(See also Introduction, Chapter 2, section 10.)
We now resume the proof that Definitions 1,2, and 3 of Hn(C*,M) E.g., let
yield canonically isomorphic groups, all integers 'C*
and
as in Definition 2.
~*
be as in Definition 1 and let
Then (taking
cochain complex such that
o T = M,
D*
n. be
R*= 'C*, S*=D*, T* = the i
T = 0,
all
i
~ 0)
by the
Note, Lemma A, we have that the natural mapping is an isomorphism: n n H (' C* 0 D*) ~ H ( 'C* ~ T*) , A A
623
Finite Generation all integers
n.
Otherwise stated, Definitions 1 and 3 give
canonically isomorphic groups. the ring equals
A
On the other hand (replacing
by the opposite ring
y.x
in
A, all
such that
x,y€A),
as in Definition 3 then letting
if
'e*, ¢*
R* = D*,
and
p* = ¢*
D*
are
in the Ler:una,
we have that the natural mapping is an isomorphism: Hn ( I e *
@
D*) ':;. Hn (e *
A
all integers
@
D* ) ,
A
Otherwise stated, Definitions 2 and 3 give
n.
canonically isomorphic groups. Finally, Definition I is independent of the choice of 'e*, ¢*. any
D*
(Proof:
Given another such, say
as in Definition 2.
1, using either
'e*, ¢*
or
'e*, ¢*
then choose
Then we have shown that Definition "e*, T*,
to Definition 2 using the fixed independent of
"e*, T*,
D*.
is canonically isomorphic Therefore Definition I is
up to canonical isomorphism).
Similarly,
Definition 2 (respectively: 3) is likewise independent of the choice of
0*
(respectively:
If we fix
e*
and let
of
'e*,¢*,D*).
Q.E.D.
M vary, then the assignment:
M~H~(e*,M)
is an exact connected sequence of functors: and the
assignment:
e*-tHn(e*,M)
is also such a sequence.
every (z-indexed) cochain complex of right A-modules for every left A-module
Also, for e*
and
M we have the universal coefficients
spectral sequence, a left half plane spectral sequence with
E~,q = Tor~p (H q (e*) ,M)
and abutment
H~ (e* ,M) .
(The abutment
always has a discrete filtration such that the union of all the filtered pieces is all of
H~(e*,M)}.
(We sometimes call this
spectral sequence the first spectral seguence of percohomology).
Chapter 5
624
Proof: If
C*
A-modules, then regard
M,
-n
complex of right
as a cochain complex in the usual
,
d
n
=d
Then for any left A-module
-n
-n
A
define
C*
n C =C
way, by defining
(~-indexed)chain
is a
Hn (C*,M) = HA (C* ,M),
all integers
n.
A
Then if
denotes the abelian category consisting of all non-negative chain complexes of right A-modules, then by [RP.WeJ,chapter I, section 1, Theorem 2, pg. 115, we have that
A has enough projectives.
Also, if we fix a left A-module
then the assignment:
n is a system of left
~
M,
0,
A.
derived functors on
(Proof:
clearly an exact connected sequence of functors.
If
It is C* E A
is
projective, then by [P.P.W.C.], Chapter I, section 1, Theorem 2, we have that
Ci "" Di Ell Di - l ,
i
~
0,
where
Di
is projective,
i
~l,
in such a way that the boundary map:
d :C -+ C _ corresponds i i i l D Ell D projection~D inclusion~D E& D i-I i-l i-I i-2' i
to the composite: all integers i
~
1.
It follows readily that
Hn(C*@M) = 0,
n~l.
A
But since
C.
is projective,
1
i
~
0,
C.
is flat, all integers
1
so that by Definition 1 ( (c- n ) nE.?' is non-pos., so bdd. abOVE
i ~ 0, A
H (C*,M)=H (C*@M), n
n
all integers
all integers
A
n
~
the axioms (Hl),
1,
all
(H2),
C* E A
n.
Therefore
that are projective.).
From
(H3), Chapter I, section 2, of [RP.we.],
pg. 117, it follows that, in the terminology of Chapter I, n ~ 0,
section 2, of [PE.WCJ that the assignment:
are the right hyperderived functors of the right exact functor ~
N®M
from the category of right A-modules into the category
A
of abelian groups.
Therefore,
[P~WCJ,Chapter
I, section 2,
Theorem 1, pg. 118, we have two spectral sequences.
The second
625
Finite Generation of these spectral sequences is a first quadrant homological spectral sequence:
If now regard
C*
is any non-positive cochain complex, then we
C*
as a non-negative chain complex in the usual fashion, -n (by requiring that C = C ,etc. ) . Then the indicated homon
logical spectral sequence becomes a third quadrant cohomological spectral sequence, with A (Hq(C*) M)= Hn(C* M) EP,q=Tor 2 -p , A" This proves the assertion in the case that Suppose now that
C*
is a
~-indexed)
C*
is non-positive.
cochain complex of right
A-modules that is bounded above (i.e., such that there exists an integer
N
such that
i C = 0,
i
all
~ N + 1) •
Then making appro-
priate dimension shifts, we obtain the indicated spectral sequence from the case that C*
be an arbitrary
modules.
~-indexed)
For each integer
complex of
C*
C*
N,
is non-positive.
Finally, let
cochain complex of right Alet
C*(N)
be the subcochain
such that
ci ,
I
=
1m (d
i < N,
N- l CN-l ;
~
CN) ,
i
= N,
i > N.
0,
Then we have the indicated spectral sequence for the cochain complex limi t at
C'(N)' N ++00
for each integer
N>
o.
Passing to the direct
gives the desired univeral coefficients spectral
Chapter 5
626
sequence for
C*,
a left half plane cohomological spectral
sequence, such that the filtration on the abutment is discrete (i.e., such that zero is a filtered piece of the n'th group H~(C*,M)
of the abutment, all integers
n),
and such that the
union of the filtered pieces of the n'th group of the abutment, H~(C*,M),
Example 1. flat over
H~(C*,M),
is all of If
C*
A,
all integers
is extremely flat over
Q.E.D.
n.
A,
or if
M
is
then
H~ (C* ,M) '" H~ (C* 13 M),
all integers
n.
A
(Whether or not the hypotheses of Example 1 hold, the groups on the right side of this equation were called traditionally the cohomology of
C*
call the ones
H~(C*,M)
efficients in
M,
Example 2. of
Let
with coefficients in
n.
percohomology groups of
C*
with co-
to avoid any confusion.) A = '1' / 4;;",
('1' / 4'1') -modules wi th
all integers
M, which is why we
Then
and let n
C = '1' / 44' , C*
C* d
n
be the cochain complex = (mul tiplica tion by 2),
is flat over
A.
Let
M=O'/2O'.
Then it is easy to see that n H (C*) = 0,
all integers
Therefore (e.g., taking
n.
'C* = (the zero cochain complex) in
Definition I, or if one prefers using the universal coefficients spectral sequence) we have
H~ (C* ,M) = 0,
Hn(C* 60 0'/40'
for all integers
0'/20') "'7/20',
n.
all integers
However,
n.
Finite Generation Therefore, the condition tion 1 (and likewise on weakened to "flat".
627
"extremely flat" on C*
'C*
in Defini-
in Example 1) cannot in general be
Also, by Example 1, it follows that
an example of a flat cochain complex of
C*
is
(7/47)-modules that is
not extremely flat. Example 3.
Suppose that
exists an integer
N>0
A
Tor + ( ,M) N l
M
is a left A-module such that there
such that
,,0.
Then in Definition I, the condition on extremely flat", Proof:
can be weakened to,
'C*, "'C*
that "'C*
is
is flat".
As in the proof of Proposition 2.1, P9. 110 of [C.E.H.A.]
(with "flat" replacing "projective" and "Tor replacing "Ext"), one sees
. 1 y th a t
eas~
" Tor A+ ( , M) = - 0" N l
is equivalent to:
"There exists an acyclic, flat homological resolution M
such that
0*
for this
l
P*
Now let
Then if
A-modules and
'C*
CP*:' C* .... C*
right A-modules such that integers
n,
i>N+I".
C*
of
Therefore, constructing
as in Definition 2 above, we have that
is bounded below. A-modules.
for
P. = 0
P*
0*
be any cochain complex of right
is any flat cochain complex of right any map of cochain complexes of Hn(CP*)
is an isomorphism, for all
then by Definition 3 above, we have that
H~(C*,M) =Hn('C*~D*),
(1)
A
nEz. (where
But, by Lemma A, with M*
i"l 0), since
R*='C*,
5*=0*
is the cochain complex such that M*
and
0*
and
T*=M*
o
M =M,
are both bounded below, we have that
the natural map is an isomorphism:
628
Chapter 5 (2)
H
n
n ( I C* 0 D*) "';. H ( I C* 0l M*) , A A
all integers
n.
Equations (1) and (2) prove the Example. Q.E.D.
Example 4. let
Let
C*
be a cochain complex of right A-modules and
M be a left A-module. p Tor (C ,M) = 0,
(1)
wi th
q
~
q
1,
Suppose that for all integers
p,q
and in addition that
either
(2a) C*
is bounded above
or
(2b) There exists a positive integer
N
such that
Tor~+l ( ,M) ::: O. Then the natural mapping is an isomorphism, H~ (C* ,M)
"';.
Hn (C* 13 M) , A
for all integers Note.
n.
If we delete the hypotheses (2a),
(2b), but instead
strengthen (1) to read (lxtr)
C*
is isomorphic to the direct limit, over a
directed set, of cochain complexes each of which is bounded above, and all obeying hypothesis (1), then the conclusion of this Example continues to hold. proof:
Let
P*
be a flat resolution of
(2b) holds, then we can choose i > N + 1. 2, and let
Let M*
D*
P*
M.
If condition
such that
be constructed from
P*
P. = 0 l
for
as in Definition
be the cochain complex such that
M
o =M,
i M = 0,
Finite Generation
629
Then exactly the same argument as the Proof of Lemma A,
itO.
Case 1, shows that the mapping of cochain complexes: C* 13 0* A
-+
C* 13 M* A
induces an isomorphism on cohomology.
(And if we have the
hypotheses of the Note to the Example, then the Proof of the Note to Lemma A proves this assertion.)
But by Definition 2,
n
H~(C*,M) =H (C*I9D*), A
so this latter observation proves the Example. Remarks 1.
Notice, by Definition 1, respectively:
2, that for every integer
n
M~>H~(C*,M), respectively:
C*, respectively:
M,
Definition
we have that the assignment:
C*~>H~(C*,M), preserves direct
limits over directed sets, and is also a half where
Q.E.D.
exact functor;
runs through the abelian category
of cochain complexes of right A-modules, respectively: the abelian category of all left A-modules, and C*,
cjJ*: C*
0* -+
Also, it is clear from Definition 1, that if
C*
are cochain complexes of right A-modules, and if 0*
is a map of cochain complexes such that
an isomorphism, for all integers
H~ (cjJ* ,M): H~ (C* ,M)
-+
n H (cjJ*)
is
n, then
H~ (0* ,M)
is an isomorphism, for all integers
M.
respectively:
is fixed. 2.
and
M,
n,
and all left A-modules
630
Chapter 5
Lemma 2.1.1. ~-indexed
Let
A
be a ring with identity, let
C*
cochain complex of right A-modules and let
left A-module.
Let
'C*
be a
right A-modules, and let
~-indexed
¢*:' C* -+ C*
A
Tor + ( ,M) ::: 0 N l A n Tor ('C ,M) = 0, p
cochain complex of
Hn(¢*):Hn(,C*) -+Hn(C*)
n,
such that
for some integer
all integers
M be a
be a map of cochain com-
plexes of right A-modules, such that is an isomorphism, all integers
be a
and such that
N':' 0,
n,
all integers
p':' 1.
Then there are induced canonical isomorphisms,
H~ (C* ,M)
':-
n H (' C* t9 M) ,
all integers
n.
A
Proof:
Follows immediately from Remark 2 above and Example 4.
Corollary 2.1.1.1.
Let
A be a ring with identity and let
be a non-zero divisor in the center of the ring a
A.
(z-indexed) cochain complex of right A-modules, and
Let
t C*
be
'C*
be a (z-indexed) cochain complex of right A-modules and let ¢*: 'C* .... C*
be a map of (z-indexed) complexes of right A-modules is an isomorphism, all inte-
gers
n,
and such that the right A-module
t-torsion, all integers
n.
'c n
has no non-zero
Then there are induced canonical
isomorphisms, n
H~ (C* ,A/tA) Q:' H (' C* @(A/tA», A
Finite Generation all integers Proof:
631
n.
Since the element
with identity
A
t
is in the center of the ring
and is a non-zero divisor, it is easy to see
that, for every right A-module
C,
we have that
C/tC,
i = 0
I
A
Tor. (C,A/tA) '= (precise t-torsion part of ~
C) ,
0,
(E.g., see Chapter proof).
i :> 2.
8,
Lemma 2, in the case
r =1
for a
Therefore the Corollary follows form Lemma 2.1.1.
Example 5.
Let
C
a cochain complex
be any right A-module. C*
Regard
C
as being
of right A-modules by defining
n'=O
Cn = {C, 0,
Let
i '= 1
n
Ji O.
M be any right A-module.
The~e.g.,
by Definition 2,
A
n
HA (C*,M) '" Tor __ (C,M), n all integers ring
A,
integers
n.
Notice that these depend very strongly on the
and that the groups may be non-zero for some negative n
(but in this case vanish for all positive integers
n) •
Remark 3. If M
is a cochain complex of left A-modules and if
is a right A-module then we have similarly the percohomology
groups where AO
C*
H~ (M, C*). Explicitly, these are defined to be H~O (C* ,M) , AO is the opposite ring of A, such that X ' Y in
equals
y' x
Proposition 2.
in Let
A. A
be a ring with identity and let
be a non-zero divisor in the center of
A
such that
A
tEA is
632
Chapter 5
t-adically complete.
Let
C*
be a cochain complex of left
A-modules, indexed by all the integers, such that m C
(1) Let
n
is t-adically complete, all integers
be a fixed integer.
n (* ) H (A/tA C*) n
A
and if the ring
Then if
is finitely generated as
'
m.
(A/tAl-module,
A is left Noetherian, then is finitely generated as A-module;
and there exists a fixed integer tha t conditions (2), Proof.
r > 0
(depending on
n)
such
and (6) of Proposition 0 hold.
(4)
The proof of the Proposition makes use of Corollary 3.1
below. Let
'C*
be a
(z-indexed) cochain complex of left A-modules
such that (multiplication by t): integers
n,
'C
n
-+ 'C
n
is injective, all
and such that we have a mapping
q,*: 'C* -+C* of cochain complexes of left A-modules such that isomorphism of left A-modules, all integers n C
q,*
(C*ll\t=c*.
Therefore, if
under the functor
Corollary 3.1 below,
"At"
(q,*ll\t
('1>*)l\t
n.
n, we
denotes the image
(=t-adic completion), then by
induces an isomorphism on coho-
mology in all dimensions,
all integers
is an
Then, since
is a t-adically complete left A-module, all integers
have that of
n.
Hn(q,*)
By Corollary 2.1.1.1 above,
Finite Generation
H~(A/tA,C*) '" Hn('C*/t.'C*), But
'C*/t.'C*'" ('C*)At/ t . (,c*/,t.
But, by Corollary 3.1, integers
n.
~(A/tA,C*)
('Cn)At
633
all integers
n.
Therefore
has non non-zero t-torsion, all
But by hypothesis the left (A/tA)-module is finitely generated, for a fixed integer
n.
Therefore by equation (4) the left (A/tA)-module Hn(A/tA) 0 ('C*)At) A
is finitely generated for the fixed integer (Z-indexed) cochain complex
('C*)At
n.
But then the
of left A-modules obeys
all of the hypotheses of Theorem 1, including
(*n)'
Therefore,
by Theorem 1, is finitely generated as A-module, and we have that (9)
There exists an integer
r'::' 0,
depending on
n,
such
that all the conditions of Proposition 0 hold for the cochain complex
('C*)At,
and in particular conditions (2), (4) and (6)
of Proposition 0 hold for
('C*)At.
Considering the equation
(3), we see that equations (8) and (9) imply, respectively, the conclusion (1) and the latter conclusions of this Proposition. Q.E.D. Remark 1.
Slightly more can be said under the hypotheses of
Proposition 2 above.
(See Remark 2 following Proposition 0'
at the end of this chapter).
Chapter 5
634 Remark 2.
Let
C*
A-modules, where left A-module.
be a A
(Z-indexed) cochain complex of right
is any ring with identity.
Let
M
be any
Then in addition to the "universal coefficients"
spectral sequence above, there is also induced a spectral sequence, confined to the lower half plane, such that
We call this spectral sequence the second spectral sequence of percohomology.
Suppose that either (1) the cochain complex
is bounded above (i.e., that there exists an integer
A
q 2:D + 1.
H~ (C* ,M)
of
H~(C*,M)
,
all integers is
either
C*
holds,
H~ (C* ,M) ,
EP,q
(finite, descending) filtration n,
such that the associated graded
(The condition, for an integer
H~(C*,M)
H~(C*,M)
be finite, means, as usual,
is a filtered piece, and also
that the zero group is a filtered piece, of First, consider the case in which
Then making the usual notation shift: C*
A-modules.
(I.e., when
n E: Z, is an abutment for the second spectral
that the whole group:
regard
all integers
is bounded above or condition (2) above on the Tor's
that the filtration on
Proof:
n,
of this spectral sequence.
sequence of percohomology). n,
all integers
q
Then there exists a
on
such
or (2) that there exists an integer
n
Tor (C ,M) =0,
such that
D
i.:: N + 1)
for
that
N
C*
C
H~(C*,M». C*
= C- n
is non-positive. d
= d- n
n ' n as being a non-negative chain complex C*
we can ' of right
But then, we have observed, in the course of estab-
lishing the universal coefficients spectral sequence (see just after Definition 3 of percohomology), that in the notations of the proof of the universal coefficients spectral sequence,
Finite Generation for any fixed left A-module A
C*....N> H (C*,M), n
n.:: 0,
M,
635
the assignment:
from the category of non-negative chain
complexes of right A-modules into the category of abelian groups, are the right hyperderived functors of the right exact functor: N- N 6 M
from the category of right A-modules into the category
A
of abelian groups.
Therefore by
[P.P.W.c.J, Chapter I, section 2,
Theorem 1, pg. 118, we have two spectral sequences.
The first
of these is a first quadrant, homological spectral sequence such that E
1 A =Tor (C ,M), p,q q p
A Hn(C*,M),
and abutment
Therefore
n>O.
Rewriting in cohomological
notation, this gives the desired cohomological spectral sequence (a third quadrant cohomological spectral sequence) in the case that
C*
If now
is a non-positive cochain complex of right A-modules. C*
obeys hypothesis (I), i.e., is bounded above, then
shifting degrees we again obtain the spectral sequence (0), (with abutment n E: Z). C*
Hn(C* M) A
'
,
n EZ,
having finite filtration, each
That proves the assertion under hypothesis (1).
is any (Z-indexed) cochain complex of right A-modules, then
define
C(N)
to be the sub-cochain complex such that
ci
,
C~N) = 11m (dN- l :
N l
c -
+
cN~
0,
Then
C'(N)
obeys condition (1), all
i
i=N i>N+l. N E: Z ,
so we have the
second spectral sequence of percohomology for gers
If now
N.
Passing to the direct limit as
half plane spectral sequence such that
N+ +
C'(N)' OD
all inte-
gives a lower
Chapter 5
636
EP,q = HP (Tor A (C* ,M», -q
2
all integers
p,q.
If condition (2) should hold, then the
second spectral sequences of percohomology of efficients in
M
C(N)
are all confined to the strip
(See Note 3
the spectral sequence. Notes 1. i.e., if
nEZ,
Notice that, if condition i
c
=
°
for
i.:::.N + 1,
M
each
below~
Q.E.D.
(1) should hold for
for some integer
is confined to the region
It
serve as an abutment for
second spectral sequence of percohomology of cients in
-D.2. q.2. 0.
H~(C*,M),
follows readily that in this case the groups with a finite filtration, each
with co-
then the
N
C*
C*--
with coeffi-
p'::'N, q.::.O.
(This can
be turned into a first quadrant homological spectral sequence after re-indexing). 2.
A
If
n
C*
Tor (C ,M) = 0, q
some integer
is such that condition (2) holds (i.e., all integers
O},
n,
q.:::. D + 1,
all integers
for
then the second spectral sequence of perco-
homology is confined to the region
-0,::, q.::.
°
(an "infinite
horizontal strip"). 3.
Notice that, in discussing the universal coefficients
spectral sequence, and the second spectral sequence of percohomology, that we took direct limits of spectral sequences of abelian groups over the directed set of positive integers.
Per-
haps some discussion is in order. Let (IN)
D
be a directed set, and for every
(EP,q (N), dP,q (N), ,p,q (N» r r r p,q,rEz, r>2
NE 0 be a
let (whole plane),
doubly graded cohomological spectral sequence of abelian groups defined for
r 22,
with
E -term 00
EP,q(N). 00
(,** (N) r
denotes
Finite Generation the isomorphism from the cohomology of r ~2.)
Suppose also that, for every
637
E;*(N) nEz,
E;~l(N),
onto
Hn(N)
is a fil-
tered object with decreasing filtration together with isomorphisms:
all integers
p,q(oZ, n=p+q,
Suppose that, whenever the spectral sequence and a map
SN,M
(IN)
in
NED.
0,
we have a map
into (lM),of bidegree
aN,M
(2 ) into N Suppose also that the maps aN,M'
) M
all
such that
N < M < R.
TP,q=limTP,q(N), r NED r then
(2
aN,N = identity of (IN)'
and such that M,N,R ED
from
(0,0) ,
of filtered objects from
that is compatible. are such that
M> N
all
Then if we define
all
p,q,rEz
(EP,q dP,q, p,q) r ' r 'Tr p,q,rE;z, r>2
with
r>2.
is a (whole plane), doubly
graded, cohomological spectral sequence, and of course is the direct limit of the spectral sequences
E~,q
denotes the
Eoo-term of this spectral sequence, then it is
not in general true that
It is true that the permanent boundaries in limit of the permanent boundaries in wi th
r':' 2,
EP,q r
E~,q(N),
all
but the permanent cycles in
the direct limit of the permanent cycles in
is the direct p,q,r EZ
is not in general EP,q(N) r
for
NED.
Chapter 5
638
However, if (4)
For every pair of integers integer
r=r(p,q)
such that
all
there exists an
depending on the pair
r'.:.r(p,q)
d~:q(N) = 0,
p,q,
p,q
implies that
NED,
then the permanent cycles in
EP,q(N)
e.g.
2
the same as the (r-2)-fold cycles,
where
for all
NED
r = r(p,q).
are
Therefore,
if condition (4) should hold, then we get equation (3). Always, if we define (5) Then
~
n n H = lim H (N), NED
all integers
n,
is a filtered abelian group, and
(6)
all integers
p,n.
Thus, if equation (3) should hold (which is
always the case if condition (4) should hold), then we have isomorphisms: (7)
all integers
p,q,n
filtered objects
Hn,
with
n = p + q.
n E;Z,
Thus, in this case, the
serve as an abutment in the usual
sense of the direct limit spectral sequence (EP,q dP,q p,q) r ' r ,T r p,q,rE;z, r>2. Example 1.
If for every integer
n,
there exists an integer
n n p = p(n) such that F H (N) = 0 for all NED, then F H = O. P P n Therefore in this case the filtration on H is discrete, all
Finite Generation integers
639
n.
Example 2.
If for every
NED,
we have that
n U F H ", Hn. pEZ p
then
Example 3. (8)
Suppose that For every integer E"'E(n) that
E
n,
such that p' g' 2
'
there exists an integer
p'
~p(n),
all
(N) '" 0,
p' +g' "'n,
implies
NED.
Then clearly condition (4) above holds (namely, take r(p,g) =E(p+g) -p),
and therefore we have eguation (3), and
therefore also eguation (7), above. The filtration on
(9)
n,
all
Hn(N)
N),
for some integer
n H
is discrete, all integers E P ' ,g' (N) = 0,
In fact, by condition (8),
such that
p' + g' = n,
follows that
all
p'
~p(n).
p' ,g'
Fp,Hn(N) =Fp'+lHn(N),
By eguation (2 ) , it N p' ~l?(n).
all integers n
FE(n)H (N) = 0,
Passing to direct limits, it follows tha t
n
FE (n) H = 0,
all
NED.
all in-
n.
Example 4.
Thus, we see that, if conditions (8) and (9) hold,
and if also the union of the filtered pieces of of
all
n.
00
Therefore, eguation (9) implies that
tegers
depending on
p
then also
(10) The filtration on Proof:
is discrete, all integers
NED,
(This means that nand
If also
n H (N)
(each integer
n,
each
holds (i. e., the f il tered groups
NED), Hn,
n E ;Z
Hn(N)
is all
then equation (7) ,
serve as an abut-
Chapter 5
640
(EP,q dP,q"P,q) r ' r r p,q,rE;;Z,
ment for the spectral sequence
and also conditions (8) and (9) are inherited by the direct limit spectral sequence,
(as well as the condition that the n H
union of the filtered pieces of ger
n E;Z,
n H (N)
if
is all of
Hn,
has this property for all
each inte-
N EO,
see
Example 2 above). (Graphically, condition (8) says that, the spectral se(EP,q(N), dP,q(N},'tP,q(N}) r r r p,q,rE;z, r>2
quences
are zero out-
side of a region:
~c:.;Z
the line
has the property that, "if one proceeds in a
p +q = n
such that, for each integer
x;z,
south-Easterly direction" along the line a
£ = £(n)
such that all spots
outside the region
R
p +q = n,
"South-East" of
(i.e., are such that
n,
one reaches (.!2.,n -.!2.)
EP,q (N) = 0, 2
are
all
N EO).
(1)
Example 5.
In establishing the universal coefficients
spectral sequence for sequences of half plane
p
E (n)
(when
C* (N),
=
~
o.
I, (2)
C*, for
the universal coefficients spectral N ~ 0,
Therefore the hypotheses of Example 4 hold all integers
(;Z-indexed) cochain complex
A-modules, and a left A-module 0
(2)
n).
In establishing the second spectral sequence of
percohomology, for a
integer
are all confined to the left
M,
C*
of right
such that there exists an
such that A n Tor (C ,M) = 0, q
all integers
q
~O
+ I,
all integers n,
the second spectral sequences of percohomology of the cochain complexes -0
~
q
~
o.
C*(N)
are confined to the horizontal strip
Therefore the hypotheses of Example 4 hold once again.
Finite Generation Ern) = n + D + I,
(Take
all integers
641
n).
Therefore, in both cases (1) and (2) above, the respective direct limit spectral sequences are such that the direct limit abutment is compatible,
(i.e., obeys condition (7», and the
direct limit abutment has a filtration that is both discrete and such that the union of the filtered pieces is all of for each integer (4)
n.
In establishing the universal coefficients spectral
sequence for a C*,
Hn,
(~-indexed)
cochain complex of right A-modules
and in establishing the second spectral sequence of per co-
homology for a
(~-indexed)
cochain complex
C*
of right A-
modules obeying the appropriate "Tor" condition, we used the fact that the functor: C*- H~ (C* ,M),
n E ~,
commutes with direct limits over directed sets, for each left A-module
M.
This follows most easily from Definition 2 of
percohomology, since tensor product commutes with direct limits ~emark:
The two spectral sequences of percohomology can be con-
structed alternatively-without passing to direct limits of spectral sequences-by using Intro., Chapter 2, section 10, Ex. 1). (5) on
Of course, the reader should note that the filtrations
H~(C*,M)
induced by the universal coefficients spectral se-
quence, respectively by the second spectral sequence of percohomology, are of course in general different. Example.
Let
t
ring with identity
be a non-zero divisor in the center of the A
and let
M =A/tA.
Then
TO~ (C,A/tA) = 0, A
642
Chapter 5
all integers
n
~
1
TorA(C,A/tA)
and
2,
all right A-modules
C.
~
(precise t-torsion in
C),
Therefore, in this case, the second
spectral sequence of percohomology just described in the case M = A/tA
becomes the long exact sequence: n-l n n !L.-H +l(TOr1(c*,A/tA)) ->-H~(C*,A/tA) ->-Hn(C*/tC*)~ ... , and the other maps are edge homo-
(in which the map morphisms, and where whose n).
"Tor!(c*,A/tA)"
is the cochain complex
n'th term is "(precise t-torsion in
Cn)",
all integers
This long exact sequence can be of use, e.g., in estab-
lishing condition Corollary 2.1. have that
A
(*n)
of Proposition 2.
For example,
If under the hypotheses of Proposition 2, we is left Noetherian, and that
Hn+l(precise t-torsion in
C*)
(A/tA)-modules, then conditon
Hn(C*/tC*)
and
are finitely generated as (*
n
of Proposition 2, and
)
therefore the conclusions of Proposition 2, hold. (The proof of Corollary 2.1 follows from the long exact sequence of the last Example, and from Proposition 2.) Proposition 3.
Let
A
be a ring with identity and let
be an element of the center of the ring is a non-zero divisor.
Let
C*
and
A.
D*
n.
of cochain complexes of left A-modules.
Suppose that
tEA
be (Z-indexed) cochain n C
complexes of the left A-modules such that t-adically complete, all int..egers
tEA
Let
and
Dn
¢*:C* ->- D*
are be a map
Then the following two
conditions are equivalent: (1)
Hn(¢*):Hn(C*) ->-Hn(D*)
is an isomorphism, all integers
n. (2)
The induced map on percohomology modulo
t:
Fini te Generation
H~ (A/tA, CP*): H~ (A/tA, C*) -+ H~ (A/tA, 0*) integers Note:
643 is an isomorphism, all
n.
If we drop the hypothesis that the element
tEA
is a
non-zero divisor, then the Proposition remains true, if in condition (2) we replace
throughout with
IIF; IT] (
,71. IT]/T • 7l. IT]) ".
Proof.
Since
tEA
exact sequence:
is a non-zero divisor, from the short
0 -+ A ~A -+ (A/tA) -+ 0
we deduce the long exact
sequence of percohomology: n-l n d_ _~Hn (C*) .....!..>H n (C*) -+ H~ (A/tA, C*)...£.....> ... (note that
since
A-module), and similarly for (1)~(2).
0*.
It remains to show that
A
is flat as right
Therefore by the Five Lemma (2)~
(1).
Assume (2);
to prove (1). Choose 7l.-indexed cochain complexes modules such that we can insist that
'Cn, 'Cn,
'On ,on
'C*,
'0*
of left A-
are flat left A-modules (in fact, be free left A-modules), and such
that we have maps of (71.-indexed) cochain complexes of left Amodules:
'C* -+C*,
'0* -+0*
that induce isomorphisms on coho-
mology: Hn ('C*) ~ Hn (C*), Hn ('0*) ~ Hn (0*), and such that we have a map
all integers
'cp* : 'C*-+'O*
of
n,
7l.-indexed co-
chain complexes of left A-modules such that the diagram:
'cp* >'0*
'C*
j C*
CP*
1
> 0*
Chapter 5
644 is commutative. integers
n,
n C
Then since
is t-adically complete, all
the image of the map
'C* -+ C*
under the functor,
"t-adic completion", is a mapping of (Z-indexed) cochain complexes of left A-modules: ('C*)/\ -+C*. ('D*)/\
Similarly for
and
D*.
We therefore deduce a commuta-
tive diagram: '¢*
'C*
.J.
( 'C*) /\
(1)
- - - > , D*
J. /\
(' *)/\
!C*
dJ
> (' D*)
.L.
¢* >
D*
The image of this diagram under the additive functor
n H
is a
commutative diagram: n H (' ¢*)
n H ('C*) (2)
""
>
1
Hn ( ( , C* ) /\ )
I
all integers
1
Hn «,¢*)/\)
> Hn ( ( , D* ) /\ )
J
n H (¢*)
V
n H (C*)
>
n > O.
Hn ('D*)
""
Hn(D*)
The composite of the left (respectively:
right) column in the commutative diagram (2) is an isomorphism since the mapping of cochain complexes: '0* -+ 0*)
'C* ..,. C*
(respectively:
was chosen so as to induce an isomorphism on cohomology
in dimension
n,
all integers
upper (respectively:
n.
From commutativity of the
lower) square in diagram (2), and the fact
that the composite of each column in the diagram (2) is an isomorphism, we see that to prove that the mapping
n H (' ¢*)
(re-
Finite Generation n H (¢*»
spectively:
645
is a monomorphism (respectively: epimor-
phism) it suffices to prove that the mapping monomorphism (respectively: epimorphism).
Hn«,¢*)A)
is a
Therefore, to com-
plete the proof of the Proposition, it suffices to prove that Hn«,¢*)A)
is an isomorphism, all integers
Since
'Cn
is flat as left A-module,
zero t-torsion, t":
'cn
->-
'Cn
"
'cn
has no non-
(since the map "left multiplication by
can be obtained by throwing the monomorphism of
right A-modules "left multiplication by functor
n.
t": A ->- A,
through the
n @IC ,,). A
('C*)A/ti«'C*)A)"" 'c*/ti(,c*),
Also so that (3)
Hn ( ( , C* ) A/ t i ( ( , C* ) A ) ) "" Hn ( ( , c * ) / t i ( , C*) ) Hn«A/tiA)@ ('C*», A
all integers the map
'C*->-C*
and such that n.
n, i
with
i > O.
The cochain complex
are such that
Hn (C*) ->- Hn (C*)
'C
n
'C*
and
is flat as left A-module,
is an isomorphism, all integers
Therefore by Definition I of percohomology, (4)
n H «A/tA) 0 ('C*»
"" H~ «A/tA) ,C*),
A
all integers
n.
Similarly for
'0*.
Therefore, by equation
(2) in the statement of the Theorem, we have that the mapping: (5)
(A/tA)
~
(' ¢*):
(A/tA)
~
A
A
('C*) ->- (A/tA)
@
('0*)
A
induces an isomorphism on cohomology in all dimensions. (multiplication by
t):
'C*->- 'C*
Since
is a monomorphism, we have
Chapter 5
646
the short exact sequence of cochain complexes of left A-modules: 0+ [('c*/t('c*)]"ti-l">[('c*)/ti(,c*)] + [('c*)/ti-l(,c*)] +0 all integers
i ':'1,
a portion of the long exact sequence of
cohomology of which is the exact sequence: n-l _d_>Hn ((A/tA) 0 ('C*»"ti-l">Hn«A/tiA) 0 ('C*»
(6)
A
Hn ( (A/ti-lA) ®
+
A
n
('C*»~ ... ,
A
all integers "D*"
i > 1.
replacing
We have a similar long exact sequence with
"C*" ,
for each integer
i.:: 1,
and
' ¢*
in-
duces a map from the long exact sequence (6) into the corresponding long exact sequence for
'D*.
Since the mapping (5)
induces an isomorphism on cohomology, from the Five Lemma and the map of long exact sequences induced by
'¢*
from the se-
quence (6) into the corresponding long exact sequence with "'0*"
replacing
"'C*",
we have, by induction on
i,
that the
mapping Hnl(A/tiA) ~ ('¢*»: Hn((A/tiA) ® ('C*» A A is an isomorphism of left with
i> O.
(A/tiA)-modules, all integers
This last equation and equation (3) for
the analogue of equation (3) for (7)
+Hn((A/tiA) ® ('D*» A
D*,
n, i
C*,
and
imply that the mapping
Hn«(A/tiA) 0 ('¢*)/\): Hn«A/tiA) 0 ('C*)/\) + . A A Hn ( (A/tlA) 0 (' D*)/\) A
is an isomorphism, all integers
n, i
with
i > O.
But then,
the short exact sequence of Corollary 1.2 of Chapter 3.applied to the complete cochain complexes of left A-modules
('C*)/\
Finite Generation and
('D*)A
647
implies that the mapping
is an isomorphism, all integers
n.
Q.E.D.
In the proof of the preceding Proposition, the commutative diagram (2) implies that mand of all
In fact, it is true that
Hn«'C*)A).
n E 7l.,
where
is canonically a direct sum-
Hn(C*)
(' C*)A
Hn(C*)ll;jHn«'c*)A),
is constructed as in the proof of the
preceding Proposition.
This follows from
corollary 3.1.
be a ring with identity and let
Let
A
an element in the center of the ring divisor.
Let
C*
be any
~-indexed
A
t
be
that is not a zero
cochain complex of t-adi-
cally complete left A-modules, and let
'C*
and
¢*:'C*+C*
be a (z-indexed) cochain complex of left A-modules and a map of z-indexed cochain complexes of left A-modules, such that (multiplication by t): 'C* -+ 'C* is injective, and such that Hn (¢*): Hn(,C*) .... Hn(C*) is an isomorphism of left A-modules, all integers
n.
Let
be the t-adic completion of
('c*t
'C*.
Then (1)
(multiplication by
t):
('C*)I\-+(,c*)"
is injective, and the mappings:
are isomorphisms of left A-modules, all integers n. n has no non-zero t-torsion, by Lemma 1.1.1 Proof. Since 'C following Theorem 1 of Chapter non-zero t-torsion, all integers of the Corollary.
4, we have that
n.
('Cn)A
has no
This proves conclusion (1)
Therefore, since also
t
is a non-zero
Chapter 5
648
divisor in the ring
A,
by Corollary 2.1.1.1 following Example
1 above, (after Definition 3 of "percohomology"), we have that the natural mapping of left (A/tA)-modules is an isomorphisl (3)
But
H
n (A/tA, (' c*)I\) ':;. Hn (A/tA) ~ (' C*)I\), A A
(A/tA) ~ ('C*)I\ RO(A/tA) ~ ('C*). A A (4)
all integers
Therefore
Hn«(A/tA) ® ('C*)I\)R:Hn(A/tA) ® ('C*», A A
Since by hypothesis the mapping,
¢*:
isomorphism, all integers
'C*+C* i,
all integers
"multiplication by
is injective, and since the element and since the mapping
n.
tEA
t":
'C* + 'C'
is a non-zero divisor,
is such that
n H (¢*)
is an
we have by Corollary 2.1.1.1
that (5)
n H (A/tA, C*) R: Hn ( (A/tA) ® 'C*) , A A
all integers
n.
Equations (3), (4) and (5) imply that the mapping of left (A/tA) -modules, (6)
H~ (A/tA, (' ¢*)I\): H~ (A/tA, (' c*)I\) + H~ (A/tA, C*)
is an isomorphism of left (A/tA)-modules, all integers Since by hypothesis
C*
complete left A-modules,
n.
is a cochain complex of t-adically (and since clearly also
('C*)I\
is a
cochain complex of t-adically complete left A-modules), the fact that the mappings (6) are isomorphisms, all integers
n,
and Proposition 3 applied to the mapping:
completes the proof of the Corollary.
Q.E.D.
Finite Generation Corollary 3.2.
Let
A
be a ring with identity and let
an element in the center of the ring zero divisor.
Let
C*
n.
A
such that
t
t
be
is not a
be a (z-indexed) cochain complex of n C
left A-modules such that gers
649
is t-adically complete, all inte-
Then there exists a (z-indexed) cochain complex
of left A-modules and a map
¢*:
'C* .... C*
'C*
of (Z-indexed) cochain
complexes of left A-modules such that (1)
(multiplication by
t):
'C* .... 'C*
is injective, such
(2)
that n 'C is t-adically complete, all integers
n,
and
such that is an isomorphism of left A-modules, all integers Proof:
Let
'0*
be a
A-modules such that gers
n
n.
(Z-indexed) cochain complex of left
'on
has no non-zero t-torsion, all inte-
(in fact, we can even construct
is a free left A-module, all integers
0*
n),
such that
'On
and such that we
have a mapping of cochain complexes of left A-modules
p*:
'0* .... C*
such that is an isomorphism of left A-modules, all integers
n.
'C* = ('0*)",
and
Then by the Corollary 3.1, if we define ¢* =(p*)
",
then
'C*
and
¢*
obey conclu-
sions (1), (2) and (3) of this Corollary.
The hypothesis in Corollary 2.1 that the element a non-zero divisor in
A
can be eliminated.
Q.E.D.
tEA
be
Chapter 5
650
More precisely, Theorem 4.
Let
A be a ring with identity and let
element in the center of the ring cally complete.
Let
C*
such that
A
tEA A
be an
is t-adi-
be a cochain complex of left A-modules
indexed by all the integers, such that m C
(1) Let
n
is t-adically complete, all integers
be a fixed integer. Hn(C*/tC*)
(2)
m.
Then if
is finitely generated as left (A/tA)-
module, and . ' . Hn+l ( preclse t- t orSlon ln
(3)
C*)
is finitely generated
as left (A/tA)-module, and if the ring
A
is left
Noetherian, then (1)
Hn(C*)
is finitely generated as left A-module,
and there exists a fixed integer
r >0
(depending on
n)
such
that conditions (2), (4) and (6) of Proposition 0 all hold. Proof:
Let
A[T]
over the ring
A,
be the polynomial ring in one variable
T
and let
B=A[T]"T be the completion of
A[T]
for the T-adic topology.
is an element of the center of the ring divisor in
B.
Also
B
is also left Noetherian.
B
B/TB = A
T
and is a non-zero
is T-adically complete. (Since
Then
The ring
B
is left Noetherian
by hypothesis, this latter observation follows from Lemma 1.1.1, with
"B"
and
"T"
replacing
"A"
and
At"
respectively).
Finite Generation
651
Then we have an epimorphism of rings: B+A by requiring that is isomorphic to
"T"
map into
A).
"t".
(In fact,
B/ (T-t) • B
Therefore every left A-module
comes a left B-module.
Clearly a left A-module
M
M beis finitely
generated (respectively: t-adically complete) as left A-module if and only if
M
is finitely generated (respectively: T-adi-
cally complete) as left B-module. Now let C*,
C*
be as in the hypotheses of Theorem 4.
considered as a cochain complex of left B-modules, obeys
all the hypotheses of Corollary 2.1 (with and
Then
"T"
replacing
"t").
"B"
replacing
"A"
Therefore, by Corollary 2.1, the
conclusions of Proposition 2 hold for the left B-module
Hn(C*).
Therefore the conclusions of Theorem 4 hold for
con-
Hn(C*)
sidered as left A-module. Remarks:
1.
Q.E.D.
Proposition 0, at the beginning of this chapter,
of course also admits a generalization, with "percohomology groups mod t"
replacing
"Hn(C*/tC*),
all integers
i".
Then
one does not have to assume hypothesis (0) of Proposition O. More precisely, Proposi tion 0'.
Let
A
be a ring with identity and let
be an element of the center of the ring
A.
chain complex of left A-modules such that complete, all integers (0') Let
nand
The element r
i. tEA
Let C
i
C*
tEA
be a co-
is t-adically
Suppose also that is a non-zero divisor.
be fixed integers with
r > O.
Then the six
652
Chapter 5
conditions (1), (2), •.. , (6) of Proposition 0 continue to be
"If (C*/tC*)"
equivalent, if we replace
"~(A/tA,C*)"
by out.
Also,
"H~-l (A/tA,C*)",
and
n l "H - (C*/tC*)"
and
respectively, through-
in condition (5), we replace "Theorem 2" by "Remark
4 following Theorem 2" (i.e., the generalized Bockstein spectral sequence referred to is that of
'r.*,
complex of left A-modules such that torsion, all integers
i,
where 'C
i
'C*
is a cochain
has no non-zero t-
and where we have a map of cochain
complexes of left A-modules
¢ *:
'C* -+ C*
is an isomorphism, all integers
such that
Hi (¢ *)
i).
And, Corollary 1.1 and Corollary 1.2 similarly generalize. That is, Corollary 1.1'. n
Under the hypotheses of Proposition 0',
be an integer such that there exists an integer
r> 0
let such
that the six equivalent conditions of Proposition 0' hold. Hn(C*}
is t-adically complete.
And equations (1) and (2) of
Corollary 1.1 continue to hold, if we replace respectively
"H
n-l
"H~-l(A/tiA'C*)" Corollary 1.2'.
i
(C*/t C*)"
Then
"Hn(C*/tic*)",
n i "HA(A/t A,C*)",
by
respectively
in equations (1), respectively (2). The hypotheses being as in Corollary 1.1',
equations (1) and (2) of Corollary 1.2 hold. Proof of Proposition 0', Corollary 1.1', and Corollary 1.2': By Corollary 3.2, there exists
'C*
a cochain complex of left
A-modules such that (multiplication by tive and such that
'Cn
t):
'C
n
-+ 'C
n
is injec-
is t-adically complete all integers
and such that there exists
'¢*:
'C* -+C*
n,
a map of cochain com-
plexes of left A-modules that induces an isomorphism on cohomology in all dimensions.
Then, if
nand
r are fixed integers
653
Finite Generation then Proposition 0 applies to the cochain complex implies Proposition 0' for the cochain complex
H~(A/tiA'C*)
e.g.,
=Hn('C*/t
Corollary 2.1.1.1.)
i
• 'C*),
Also, Corollary 1.2 applied to C*
2.
which
(Since
i~O, 'C*
by im-
by definition of the
generalized Bockstein spectral sequence of 'C*
C*.
all integers
mediately implies Corollary 1.2' for
lary 1.1 for
'C*,
C*.
implies Corollary 1.1' for
Finally, CorolC*.
The latter conclusions of Proposition 2 and of Corol-
lary 2.1 can be sharpened to read, "then the six equivalent conditions of Proposition 0' hold". 3.
Suppose that all the hypotheses of Proposition 0', ex-
cept possibly the hypothesis (0'), hold. that conditions (2),
Then it is still true
(4) and (6) of Proposition 0 are equivalent.
(The proof is similar to that of Theorem 4).
Also, if all the
hypotheses of Proposition 0', except possibly hypothesis (0'), hold, then one still obtains all the conclusions of Corollary 1. 2I
•
Tha t i s ,
Corollary 1.2".
Let
A
be a ring with identity and let
an element of the center of the ring complex of left A-modules such that all integers
i.
Let
nand
r
A. C
i
Let
C*
be
be a cochain
is t-adically complete,
be fixed integers with
Then if the equivalent conditions (2),
t
r> O.
(4) and (6) of Proposi-
tion 0 all hold, then equations (1) and (2) of Corollary 1.2 hold. corollarly 1.1". have that
Hn(C*)
The hypotheses being as in Corollary 1.2", we is t-adically complete. "H n ;l
[T)
(C*;l [T) /Ti .;l [T) ) "
,
of Corollary 1.1, and replaces
And, if one replaces in equation (1)
"Hn-l(C*/tiC*)"
by
654
Chapter 5
n l "HZ -[T] (C* , Z [T]/Ti·Z [T])"
in equation (2) of Corollary 1.1,
then the so modified equations in Corollary L 1 continue to hold. The proofs of Corollary 1.1" and Corollary 1.2" are similar to the proof of Theorem 4, and easily reduce, by the construction in Theorem 4, to Corollary 1.1' and Corollary 1.2', respectively.
4.
Under the hypotheses of Corollary 1.1'
(or of Corol-
lary 1.1"), suppose that we do not change the "cohomology groups mod tin
of equations
(1)
and (2) of Corollary 1.1 to the cor-
responding percohomology groups. main valid?
Then do these equations re-
(I.e., under the hypotheses of either Corollary
1.1' or of Corollary 1.1", do equations (1) and (2) of Corollary 1.1 hold as written, without making any substitutions with percohomology?)
The answer is "no", not even if
plete discrete valuation ring not a field, if
0,
of the maximal ideal of C* is such that
i
C = 0
for
n = 1 i
~
O.
C*
is a generator
0,1,2.
4, the second Example in
Remark 2 following the proof of Corollary 6.1.
properties, over
t
is a com-
and if the cochain complex
In fact, consider, in Chapter
we constructed a cochain complex
A= 0
C*
In that Example,
having the above indicated
obeys the hypotheses of Corollary 1.1'
(and therefore also those of Corollary 1.1") for the integer n = 1,
but, as we have seen in that Example of Chapter
4, the
natural mapping: HI (C*)
-+-
[li:m HI (C*/tic*)] i>O
is not an isomorphism, but is the zero map from a non-finitely generated
O-module
G~ 0
onto a zero module.
have seen in that Example of Chapter 4,
Also, as we
Finite Generation
655
O [lj,Inl H (C* /tiC*) ] "" G " O.
PO Therefore, for the cochain complex Chapter 1.1"
C*
of that Example of
4, the hypotheses of Corollary 1.1' and of Corollary
hold, yet equations (1) and (2) of Corollary 1.1 fail as
written.
Therefore one must use the indicated percohomology
groups in Corollary 1.1' and in Corollary 1.1". Example 1.
Let
0
be a complete discrete valuation ring
having a quotient field
o
K
of characteristic zero,
can be of mixed characteristic) and let
class field of bra, let
O.
A= A® k
be a Noetherian X
Suppose that
(e.g., it suffices that have,
A
and let
o
over Spec(k).
Let
X
k
(however,
be the residue
(commutativ~
O-alge-
be a scheme simple and proper
X
is embeddable ([PACJ) over ~.)
be projective over
A
Then we
([p~CJ), the lifted (~t)-adic, and the lifted (~)-adic,
cohomology groups of H H
h
h
all integers
X,
(X,~t),
A
(X,~
),
h > O.
(Here,
AA = AA t,
tor for the maximal ideal of Assume for simplicity that
O.
(At
where
t
is any genera-
is as defined in [P.P.WC.]).
A is flat over
O.
Then Theorem 1
of this chapter immediately implies that
is finitely generated as Proof:
In fact, let
m
of which are affine open.
~A-module, all integers be any covering of Then
X
h> O. the elements
656
h
~
Chapter 5
where
0,
D*
is a certain cochain complex of sheaves of
~-modules,
all of which are t-adically complete.
where
C* (ur, X,D*)
C*
=
(Since
Di
integers
Hh(x,r~),
i
c
t):
Also,
-+
c
i
0,
is flat over i.:. 0).
ci
is a cochain complex such that
t-adically complete, all integers (multiplication by
Therefore
i.
is
From the definitions,
is injective, all integers since
C* /tC*
A
is flat over
is such that
the hypercohomology of
X
0,
Hh (C* /tC*)
all R;
with coefficients in the
cochain complex of sheaves of differential forms over is therefore finitely generated as
i.
A
=
A,
(h/th)-module.
and The
Example therefore follows from Theorem 1 applied to the cochain complex
C* ,
Example 2.
the ring
A
and the element
tEA.
The hypotheses and notations being as in Example 1,
suppose we delete the hypothesis that
"A
is flat over
0".
Then the conclusion of that Example remains valid. Proof:
We use Noetherian induction on the ring
assertion is false for
A
exists an ideal
A,
in
X
over
A=
~/t~,
If the
then there
such that the assertion is false
X x Spec (A/(I +t~)) and such that the asserSpec (A) tion is true for ~/I' and X x Spec (A/ (I' + tA)) , all Spec (A) ideals I' in A such that. 11- I'. Replacing A by ~/I, for
~I
I
and
A.
and
we can assume that the assertion is true for J;;i{O}
If
in ~
~/J,
all ideals
A. has no non-zero t-torsion, then the assertion follows
from Example 1.
So we may suppose that there exists
x E (pre-
Finite Generation A)
cise t-torsion of
such that
x
to.
657
Then, we have the short
exact sequence:
(1) where
Q
A s O->-~ ->A->-- ->-0 Q xA
,
is the image in
A
of the annihilator ideal of
x
in
~
(Q~~
s
is the unique homomorphism of A-modules that sends the coset
since
x
is a precise t-torsion element), and where
of 1 into the element then
C
n
x E A.
is flat over
sequence (1) over
A
A,
If we let all integers
o ->- C* ~ (~) A
be as in Example 1,
n,
so tensoring the
yields the short exact sequence of cochain
complexes of A-modules (in fact, of (2 )
C*
AA-modules):
A
->-
C*
->-
Q
C* 0 (~) A
->-
O.
However, from the explicit construction in [P.A.CJ , A A A stands for the conwhere "D*(--=-)" C* 0 (x~) '" C* (ill , X,D* (~) ) , xA " A II A struction analogous to D* in Example 1 with the ring taking the place of
"~",
A
Xspe'b (A) Spec (~)"
and
-
Therefore, by the inductive assumption on finitely generated as A Q
is not a proper quotient ring of
we have a contradiction (since then A
~
A,
A- ( =
be a counterexample).
Therefore the ring
on~, Hh (C*
~,
0 (A/Q) )
Hh (C* ~ is A h> O. Also, if
~
then
-)module, and
X.
A xA- )
== A =
Hh(X,~) =Hh(X,f
finitely generated as
quotient ring of
A,
~A-module, all integers
replacing
~
A)
and is
is supposed to
A
A/Q
is a proper
and therefore by the inductive assumption is finitely generated as
A
~
-module, all
A
integers
h:;- O.
Therefore, from the long exact sequence of co-
homology associated to the short exact sequence of cochain complexes (2), we deduce that
Hh(C*)
is finitely generated as
658 A
~
-module, all integers
completes the proof.
Chapter 5 h,
which by equation (1) of Example 1
CHAPTER 6 THE HIGHEST NON-VANISHING COHOMOLOGY GROUP
Let
A
be a ring with identity (respectively:
an abelian category).
Let
element in the center of t:M+M
ject and let A-module
M
endomorphism that if in
A
M
M
A.
(Respectively:
be a map in
t:M
Every element of divisible part of t
M)
->
M
M M
be an
Let
is t-divisible iff iff the
Notice, therefore, if
is an endomorphism of (1)
M be an ob-
(respectively:
is an A-module (respectively:
and if
t
Then we say that the
is an epimorphism).
lowing conditions are equivalent:
(3)
A).
is t-divisible.
t:M ... M
A be
M be an A-module and let
(respectively: the object
every element of
Let
M
is an object
M),
then the fol-
M is t-divisible (2)
is t-divisible (respectively:
(2) The t-
(as defined in Chapter 1) is all of
is an epimorphism.
(Notice, also, that if
M
A-module - or, respectively, if the abelian category
M).
is an
A obeys
the axiom (P. 2) of [E. M.l - then it is also equivalent to say that "every element of
M
is infinitely t-divisible" - or, respec-
tively, that "the infinitely t-divisible part of in Chapter 1) is all of Lemma 1.
Let
A
M").
be a ring with identity (respectively:
be an abelian category), let
C*
of left A-modules (respectively: and let
t
M (as defined
be a
~-indexed
659
A
A
cochain complex
of objects and maps in
be an element in the center of
Let
A)
(respectively:
660
Chapter 6
and let C*).
t*: C*
->-
C*
be an endomorphism of the cochain complex
Suppose that (l)
(multiplication by all integers
Suppose also that
n
t): C
i
->-
c
i
is a monomorphism,
i. is an integer such that i > n,
(2)
Hi(C*/tc*)!=O'
"I 0,
i = n,
and that (3)
For each integer object)
Hi(C*)
i
~n
+ 1,
the left A-module (or
has no non-zero submodule (or non-
zero subobject) that is t-divisible. Hi(C*) =0,
(4)
!
all integers
Then
i~n+l,
Hn(C*) "10.
Also,
Hn(C*)
is not a t-divisible module, and the natural
mapping is an isomorphism of (5)
(A/tA)-modules,
n n H (C* /tC*) '" (A/tA) ~ H (C*) , A
(where the right side of equation (5) is interpreted as in Chapter 1, in the abelian-category-theoretic case, as the "Cokernel of the endomorphism
Hn(t*)
of
Hn(C*)").
Note 1.
If we replace the hypothesis (3) by the weaker hypo-
thesis:
(3')
Hn+l(C*)
has no infinitely t-divisible precise
t-torsion elements, then the conclusions of the Lemma remain valid, providing only that one replaces the sentence: Hi (C*) = 0,"
in equation (4), with
"Hi (C*)
is at-divisible
Highest Non-Vanishing Cohomology Group A-module having no non-zero t-torsion". can instead replace
"Hi(C*)"
"Hi(C*)/(t-divisible elements)"
661
(If one wishes, one
in conclusions (4) and (5) by and
"Hn(C*)/(t-divisible ele-
ments) ", respectively.) proof.
From the long exact sequence of cohomology
i-l i d . t d ••• - - » H1 (C*) -+ Hi (C*) -+ Hi (C* /tC*) - » and equation (2), we deduce that for "multiplication by Hi(C*)
t"
of
is t-divisible.
i.:':.n+l,
Hi(C*) =0,
Hi(C*)
i
~
n + 1, the endomorphism
is surjective, so that
But therefore by equation (3),
as required.
Also, a portion of the same
long exact sequence is the sequence d n- l t dn --»Hn(C*) -+Hn(C*) -+Hn(C*/tC*) -»Hn+l(C*)-+
Since
n l H + (C*)
follows that
=
0,
and by equation (2),
Hn(C*) l' 0,
t): Hn(C*)-+Hn(C*)
Hn (C* /tC*) l' 0,
it
and in fact that (multiplication by
is not surjective, i.e., that
not a t-divisible module.
Hn(C*)
is
Also, from this fragment of the coho-
mology sequence, we deduce equation (5).
Q.E.D.
The proof of the Note to Lemma 1 is similar. Remarks 1:
Suppose in Lemma 1 (that we are in the module case
and) that we delete hypothesis (1) of Lemma 1. the element
tEA
is a non-zero divisor.
(2) and (6), we change "Hn(C*/tC*)" C*
to
"Hi (C*/tC*)"
to
Suppose also that
The, if in equations "H!(A/tA,C*)"
and
"H~(A/tA,C*)" - that is, the percohomology of
with coefficients in
A/tA,
as defined in the last defini-
tion of Chapter 5 - then the rest of the Lemma continues to hold.
662
Chapter 6
The proof is the same. 2.
Suppose in Lemma 1 that we are in the abelian category-
theoretic case and that (again) we delete hypothesis (1) of Lemma 1. 0*
Then let
0*
be defined as in Chapters 1 and
2 (i.e.,
on = Cn 6l Cn + l ,
is the z-indexed cochain complex such that
n n all integers n, where d :0 n ->- on+l is such that d (u,v) = n n+l .- Cin ; +l , ) (d (u) + tv,.d (v) ), all u E d\ v and in equation (2) replace
"Hi (C*/tC*)"
by
"Hi (0*)",
then (again) Lemma 1
remains valid (in the abelian category-theoretic case).
The
proof is the same. 3.
Obvious generalizations of Lemma 1 are possible, where
the ideal 4.
tA
in the ring
A
is replaced by an arbitrary ideal.
Notice that if, under the hypotheses of Lemma 1 (or of
the more general Lemma described in Remarks 1 and 2 above), we delete the hypothesis (3), then one could still conclude that: is an
A[t-l]-module (or, in the abelian-
category-theoretic case, that all integers Hn+l(C*)
i
~n
+ 2,
Hi(t*)
is an isomorphism),
and that
is a t-divisible left A-module (or, respecn l "H + (t*) -divisible")
tively, a t-divisible (more presicely, object) . Let
A
be a ring with identity.
Jacobsen radical of
A
Then recall that the
is the intersection of all left maximal
ideals in
A - or, equivalently, of all right maximal ideals in
A.
is an element in the center of
If
t
A,
such that
t-adically complete, then it is easy to see that Jacobsen radical of
A.
t
A
is
is in the
663
Highest Non-Vanishing Cohomology Group Proposition 2.
Let
A
be a ring with identity and let
an element in the center of of left A-modules.
Let
C*
all integers
and that we have a non-negative integer Hn(C*/tC*)
(2)
elements. (3)
n
such that
i':'n+l, s
such that
is generated as left (A/tA)-module by
s
Suppose, in addition, that Either (a)
module and
t
or (b) Hn(C*)
be
be a cochain complex
Suppose that we have an integer
Hi (C*/tC*) =0,
(1)
A.
t
Hn(C*)
is finitely generated as an A-
is in the Jacobsen radical of The ring
A;
A is t-adically complete, and the A-module
has no non-zero t-divisible elements.
And finally, suppose that hypotheses (1) and (3) of Lemma 1 hold (we'll see that it follows that all the hypotheses of Lemma 1 hold).
Then
(1)
Hi (C*) = 0,
(2)
Hn(C*)
all integers
i':'n + I,
and
is generated as left A-module by
s
elements.
Also, the natural homomorphism is an isomorphism (3)
(A/tA)
@
n n H (C*) "" H (C* /tC*) .
A
Also, (4)
then
If
ul, ... ,u
ul, ... ,u h
generate
of as
h
(A/tA)-module.
are any elements of Hn(C*) in
Hn(C*),
h;:O,
as A-module iff the images
n H (C*/tC*)
generate
Hn(C*/tC*)
Chapter 6
664 Notes: tEA
1.
As in Remark 1 following Lemma 1, if the element
is a non-zero divisor, then hypothesis (1) of Lemma 1 need
not be assumed, if, e.g., in hypotheses (1) and (2) of Proposition 2, and in conclusions (3) and (4) of the Proposition, we replace "Hi(C*/tc*)"
by
"H~lA/tA,C*)'" cients in
A/tA,
"H!(A/tA,C*)",
and
"Hn(C*/tC*)"
the percohomology groups of
C*
by
with coeffi-
as defined in latter part of Chapter 5.
(Also, by Remark 2 following Lemma 1, even if zero divisor, then if we define
0*
tEA
is a
as in Remark 2 following
Lemma 1, then again hypothesis (1) of Lemma 1 can be deleted, if in hypotheses (1) and (2) of Proposition 2 and in conclusions (3) and (4) of Proposition 2, we replace "Hi (0*) " , 2.
and
n
"H (C* /tC*) "
"Hi (C*/tC*) "
by
n
by
"H (0*) ") .
And as in the Note to Lemma 1, if we replace hypo-
thesis (3) of Lemma 1 with the weaker hypothesis (3') of the Note to Lemma 1, and if we modify hypothesis (3) of this Proposition by replacing in both (3a) and (3b) that
"A
"Hn(C*) (note
by t~at
"Hn(C*)/(t-divisible elements)" (3b) so modified states simply
is t-adically complete")
then the Proposition conti-
nues to hold, where in conclusions (1), (2) and (4) throughout we replace
"Hi(C*)"
elements)"
and
and
"Hn(C*)"
by
"HiIC*)/(t-divisible
"Hn(C*)/lt-divisible elements)" respectively.
Also, the weakening of hypotheses in Notes 1 and 2 can be made simultaneously, if the modifications in the statement of the Proposition indicated in both Notes are made simultaneously. Proof.
Since the hypotheses of Lemma 1 hold (or, in the more
general case in the Note to Proposition 2, since the hypotheses of Remark 1 or 2 following Lemma 1 hold), we have that
Highest Non-Vanishing Cohomology Group
which is conclusion (1) of Proposition 2.
665
Consider the portion
of the long exact sequence of cohomology n d - l
(4)
••• _ _ >H n
By conclusion
(1)
t (C*) .... Hn (C*)
-+
dn t Hn (C*/tC*) -> Hn + l (C*) .......
n l H + (C*) = O.
of Lemma l,
the long exact sequence (4), we have that
Therefore, from (A/tA)
(;9
n H (C*) ""
A
which proves conclusion (3) of the Proposition. be such that the images ul, ... ,u h
in the group (5)
(""Hn(C*/tC*)
of
by conclusion (3) of
the Proposition) generate the group (5) as (A/tA)-module. let
Then
M = Hn(C*).
Case 1.
Hypothesis (3a) of the Proposition holds.
a finitely generated left A-module, and therefore is also a finitely generated A-module. in
(A/tA) QM
generate
A it follows that
(A/tA) 0 N =
o.
Then
M
N=~AUl+
is ... AUh)
Since the images of
(A/tA) 0M
as
(A/tA)-module,
A Since
N
is a finitely generated
A
A-module, and since
t
is in the Jacobsen radical of
follows by Nakayama's Lemma that i.e.,
ul, ... ,u
h
generate
M
N=O.
But then
as A-module.
A,
it
M=Aul+ ... +AU , h
This proves conclu-
sion (4) of the Proposition, in Case 1. Case 2.
Hypothesis (3b) of the Proposition holds.
Then by (3b), since M
N
is a submodule of
A-module, and in
N=M"'.
has no non-zero t-divisible elements,
N.
Thus
u ' .•. , u EN h l [(A/tA)
Let
(;9
N
is a t-adically complete
are such that the images of
NJ = N/tN
generate
N/tN
as
(A/tA) -
A
module.
But then, since
A
is also t-adically complete (the
very elementary) argument in the last part of Theorem 1 of
666
Chapter 6
Chapter S implies that x EM
Now, let
ul, ... ,u h
be any element.
is generated as A-module by exist
a , ... , a E A l h
since
M
in
M.
such that
x = a 1u 1
N,
N
Then
{ul, ... ,u }, h
is an A-submodule of
x EM
generate
x EN, and since
{ul' ... ,u h }.
N
we have that there
+ •.• + a h u h
But
N.
in
it follows that
being arbitrary, it follows that
as A-module by
as A-module.
M
is generated
So again in Case 2, we have proved
conclusion (4) of the Proposition. Thus, in all cases, conclusion (4) of the Proposition is proved.
It remains to establish conclusion (2).
hypothesis (2) of the Proposition, we have that generated, as be
s
(A/tA)-module, by
such elements.
si tion, there exist
s
elements.
In fact, by Hn(C*/tC*)
is
Let
Then, using conclusion (3) of the Propon u l ' ... , Us E H (C*)
under the natural mapping.
that map into
vI'···' v s
But then, by conclusion (4) of the
Proposition (since the images
VI' ... ,v
as (A/tA)-module), we have that
s
generate
u ' ... ,u l s
generate
Hn(C*/tc*) Hn(C*)
as A-module. The proof of Note 2 to the Proposition is similar. Remarks 1.
Q.E.D.
If the hypothesis (3a) of Proposition 2 holds, and
if the hypotheses of Lemma 1 hold, then there exists an integer s > 0
such that the hypothesis (2) of Proposition 2 holds.
(Namley, (Proof.
s
=
number of generators of
Since
n (A/tA) ~ H (C*).)
Hn+l(C*) = 0,
n H (C*)
we have that
as A-module.) Hn(C*/tc*) ""
(A similar observation holds if we also relax
A
hypothesis (1) of Lemma 1, as in the Note following Proposition 2.)
Highest Non-Vanishing Cohomology Group Remark
2.
667
If the hypothesis (3b) of Proposition 2 holds, and
more strongly if
Hn(C*)
is t-adically complete, but if we
delete the hypothesis (2), then the conclusion (4) continues to hold (as do the conclusions (1) and (3), but of course not conelusion (2», and the proof is similar. Also, a strengthening of conclusion (4) can then be stated: (4')
A subset
S
of
left A-module generated by iff the image of
S
in
Hn(C*) S
has the property that the
is t-adically dense in
Hn(C*/tC*)
generates
Hn(C*)
Hn(C*/tC*)
as left (A/tA)-module. (And also, as usual, one can delete hypothesis (1) of Lemma I, if one replaces
"Hi (C*/tC*)"
"H~(A/tA,C*)'"
and
and
"H n (C*/tC*)"
by
"Hi (A/tA,C*)"
the corresponding percohomology groups, as
defined in the latter part of Chapter 5 , throughout.
And the
analogue of Note 2 of proposition 2 also holds valid.) Remark
3.
Suppose that we have all the hypotheses of Proposi-
tion 2, except for hypothesis (3)
(and that we also do not have
hypothesis (3') of the Remark following the proof of Corollary 2.2).
Then "how false" does conclusion (4) of Proposition 2 (or
as modified in the Remark following the proof of Cor. 2.2 below) become? pose that in
That is, let u l ' ... ,u h
M/tM(~E~)
as A-module?
E;
M= Hn(C*)/(t-divisible elements). M are such that the images of
generate
M/tM.
Then do
ul, ... ,u h
Sup-
u l '.··, u h generate
M
(This would be conclusion (4) as modified by the
indicated Remark following Corollary 2.2 below). The answer is, in general, no (see Example below). if we let
N = the A-submodule of
M generated by
However,
u l '·· .,u h '
668
Chapter 6
then the proof of conclusion (4) of Proposition 2 shows that
where
N
and
NAt,
(as
At A -module) by
Thus,
ul' .•. ,u ' h is an AAt-module also generated
is an A-module generated (as A-module) by the completion of u ' ... u . l h
N,
Also, we have that
is "not very far away" from being generated by
M
Example.
Let
A
be any ring with identity and let
non-zero divisor in the center of
A such that
zero infinitely t-divisible elements. not t-adically complete. even if
A
Z'.
than the zero ideal.
has no nonA
is
(Examples of such rings are legion, E.g.,
A=Z'.(p)'
localized at any prime ideal And
be any
Suppose also that
is a discrete valuation ring.
ring of integers
A
t
A = k [T] (Tk [T] )
where
(p) k
the
other
is any
field, the localization of a polynomial ring in one variable over a field
k
Then let
be any ring such that
A'
at the (prime) ideal generated by the variable).
as subrings and such that Or i f
A
we can take
(A I )A = AA .
A'iA,
such that
AcA'cA"
(E.g., we can take
A' =AA,
is a discrete valuation ring that is not Henselian, A'to be the localization of any finitely generated
etale A-algebra (that is not A-isomorphic to A) at any maximal ideal that contains the maximal ideal of
A.
Or again, if
A
is a discrete valuation ring that is not complete, we can let A'
be any discrete valuation ring that is unramified over
that "I A,
A,
and that has a trivial residue class field extension
Highest Non-Vanishing Cohomology Group over
A).
ci
Then define
. r-/. °,
= 0,
cO = A' •
l
Then
669 C*
is a
(non-negative) cochain complex of A-modules, and obeys all the hypotheses of Proposition 2, with (Also
C*
n = 0,
except hypothesis (3).
does not obey hypothesis (3') of the Remark following
the proof of Corollary 2.2 below).
But
HO(C*) =HO(C*)/(divisible elements) =A', HO (C* /tC*) = (A/tA)
@
HO (C*)
A>
and
A/tA.
A
The element
IE HO (C*)
O (A/tA) @ H (C*)
has the property
that the image in
generates this free (A/tA) -module of rank one,
A
yet I does not generate as A-module. A'tA').
(Since
A'
HO(C*)
(=HO(C*)/(t-divisible elements)
is not A-isomorphic to
A,
since
Thus the, somewhat illuminating, observation in the
above Remark, about "how true" conclusion (4) of Proposition 2 remains if we delete hypothesis (3)
(and also do not assume
hypothesis (3') of the Remark following the proof of Corollary 2.2 below), is in essence "best possible". Corollary 2.1.
Let
A be a ring with identity and let
element of the center of
A.
Let
complex of left A-modules, and let
C* n
be a
(~-indexed)
be an integer.
t
be an
cochain Suppose
that hypotheses (1) and (3) of Lemma 1, and hypothesis (3) of Proposition 2, hold. (1)
Suppose also that
Hi (C*/tC*) = 0,
all integers
i >n +1
and that (2) Then
Hn(C*/tC*)
is simply generated as
(A/tA)-module.
Chapter 6
670
(1)
Hi(C*) =0,
all integers
(2)
Hn(C*) ~A/I
as left A-module, where
determined) left ideal in
I
I
is a
(uniquely
A,
Hn(C*/tC*)~A/(I+tA)
(3)
i~n+l,
as left (A/tAl-module, where
is the ideal in conclusion (2), and An element
(4)
uEHn(C*)
A-module iff the image of Hn(C*/tc*) Note:
u
generates
in
Hn(C*)
Hn(C*/tC*)
as left
is a generator of
as left (A/tA)-module.
In Corollary 2.1 above (and also in Corollary 2.2 below)
they hypothesis (1) of Lemma 1 can be dropped, if zero divisor in "Hn(C*/tC*)"
A,
and if we replace
with
"H!(A/tA,C*)"
and
t
"Hi (C*/tC*)"
"H~(A/tA,C*)"
is a nonand respec-
tively throughout (percohomology groups as defined in the latter part of Chapter 5).
(And, even if the element
divisor, if we define
D*
tEA is a zero
as in Remark 2 following Lemma 1, then
Corollaries 2.1 and 2.2 continue to hold if we delete the hypothesis (1) of Lemma 1, and replace "Hn(C*/tC*)"
with
"Hi(D*)"
and
"Hi (C*/tC*)" "Hn(D*)"
and
respectively).
The
proof is the same. Corollary 2.2.
(E~,d~) iEZ
Under the hypotheses of Corollary 2.1, let i E if., be the (generalized) Bockstein
and
r>O spectral sequence as defined in Chapter 1 of the z-indexed cochain complex tion by Let
C*
with respect to the endomorphism, "multiplica-
t". I
be the ideal described in conclusion (2) of Corol-
lary 2.1, and let
J = {x E A:
There exists an integer
r> 0
such
Highest Non-Vanishing Cohomology Group that
t
r
tx E J,
0
x E I}.
Then the ideal
implies
J
671
has the property that
x (; A,
x E J-equivalently, that the quotient ring
has no non-zero t-torsion.
J
can be characterized as being the
smallest left ideal in the ring
A
(In particular,
such tha t I c J.
elements in the ring
having this property and J
contains all the t-torsion
Then, ~or
A).
A/J
E~
of the generalized
Bockstein spectral sequence, we have that En"" A/ 00
(1)
+
(J
tA)
as left (A/tA)-modules. For each integer
r
~
(Thus,
0, And
J =
U J
of conclusion (1) is
Then
).
r>O r (2)
J
En"" A/ (J r
+ tA)
r
Proof of Corollary 2.1.
The hypotheses of Corollary 2.1 imply
those of Proposition 2, with Proposition.
s =1
in hypothesis (2) of the
Therefore we have conclusions (I), (2), (3) and (4)
of Proposition 2, with
s = 1.
Conclusions (1) and (4) of Propo-
sition 2 immediately imply conclusions (1) and (4), respectively, of Corollary 2.1. Hn{C*) that A.
Conclusion (2) of Proposition 2 implies that
is simply generated as left A-module, or equivalently Hn(C*) ""A/I
Then
as left A-module for some left ideal
I={aEA: aox=O,
uniquely determined. 2.1.
all
xEHn(C*)},
I
in
and is therefore
This proves conclusion (2) of Corollary
Finally, conclusion (3) of Proposition 2 and conclusion
(2) of Corollary 2.1 imply conclusion (3) of Corollary 2.1. Q.E.D.
672
Chapter 6
Proof of Corollary 2.2.
The short exact sequence (*) of the
conclusions of Theorem 2 of Chapter 1, for the integer for the cochain complex of A-modules "multiplication by (*)
0+
to,
C*
nand
and the endomorphism
is the short exact sequence
n (A/tA) 0 [H (C*) / (t-torsion) 1 + En A
+
00
{t-divisible, precise t-torsion elements in n l H + (C*)} +
o.
But by conclusion (1) of Corollary 2.1, we have that
Hn+l(C*) = 0,
and therefore the third group in the above short exact sequence is zero.
Therefore the short exact sequence (*) becomes an iso-
morphism of left A-modules (5)
(A/tA)
@
A
n [H (C*) / (t-torsion) 1 ':! En. 00
By conclusion (2) of Corollary 2.1, we have that
The t-torsion in the left A-module
A/I
is
J/I,
as defined in conclusion (1) of this Corollary.
where
J
is
Substituting
this observation and equation (2) into equation (5) yields that (6)
(A/tA)
@
[(A/I)/(J/I) 1"" En, 00
A
or equivalently
which is conclusion (1) of Corollary 2.2. In one of the Remarks (Remark 3) following Theorem 2 of Chapter 1, we have established analogously to the short exact
Highest Non-Vanishing Cohomology Group sequence (*), for every integer
r
~
0,
673
the short exact sequence
(A/tA) ® [H n (C*) / (precise tr-torsion) 1
0-+
A
r-l
t
-+
H
. r • {preclse t -torsion elements in
n l
+ (C*)}
-+
o.
In the same way that equation (6') is derived from the short exact sequence (*), from equation (*r) i = n + 1,
of Corollary 2.1 with
(and by conclusion (1)
and by conclusion (2) of Corol-
lary 2.1), we deduce that
A/
(J
r
+ tAl "" En r
as left A-modules, all integers
r
~
0,
proving conclusion (2) Q.E.D.
of Corollary 2.2. Remark:
Suppose, in the statement of Proposition 2 (or of Corol-
lary 2.1, or of Corollary 2.2), we replace the hypothesis (3) by the weaker hypothesis (3')
Hn(C*)/(t-divisible elements) obeys the hypothesis (3) of Proposition 2.
(3')
Let
(More precisely:
M=Hn(C*)/(t-divisible elements).
Then Either (3'a) the element or (3'b)
tEA
M
is finitely generated as left A-module and
is in the Jacobsen radical of
The ring
A
A,
is t-adically complete.
(This is
the weakening of hypothesis (3) of Prop. 2 discussed in Note 2 to Proposition 2). Suppose also that we replace hypothesis (3) of Lemma 1 by
674
Chapter 6
the weaker hypothesis (3') of the Note to Lemma 1. Then the conclusions (1) - (4) of Proposition 2 (respectively: (1) - (4) of Corollary 2.1;
(1) and (2) of Corollary 2.2) continue
to hold, where conclusion (1) of Proposition 2 (resp: conclusion (1) of Corollary 2.1) must be changed to: (1')
Hi(C*)
is a t-divisible left A-module and has no non-
zero t-torsion, and in conclusions (2) and (4) of Proposition 2, (respectively: conclusions (2) and (4) of Corollary 2.1), one replaces
"Hn(C*)"
with
"Hn(C*)/(t-divisible elements)".
(No
change required in conclusion (3) of Proposition 2 (respectively: (3) of Corollary 2.1;
(1) and (2) of Corollary 2.2).
(And like-
wise the Notes to Proposition 2, and to Corollary 2.1, remain equally valid when condition (3') above replaces hypothesis (3) of Proposition 2, and condition (3') of the Note to Lemma 1 replaces condition (3) of Lemma 1.
Likewise, Theorem 3 below re-
mains valid when the above condition (3') replaces hypothesis (3) of Proposition 2, and also (3') of the Note to Lemma 1 replaces (3 )
0
f Lemma 1. Likewise for Corollary 3.1 below (where of course one must
replace
"Hn(C*)"
in condition «4) (a)) of Corollary 3.1 by
"Hn(C*)/(t-divisible elements)", when weakening hypothesis (3) of Proposition 2 to hypothesis (3') of this Remark, and replacing (3) of Lemma 1 by (3') of the Note to Lemma 1.) And similarly for Corollary 3.1' in Remark 1 following Corollary 3.1 (where (as usual) lary 3.1' must be changed to
"Hn(C*)"
in condition (2) of Corol-
"Hn(C*)/(t-divisib~ elements)",
when one replaces hypothesis (3) of Proposition 2 by the weaker hypothesis (3') of this Remark, and also replaces (3) of Lemma 1
675
Highest Non-Vanishing Cohomology Group by (3') of the Note to Lemma 1.)
Similarly for Remark 2 following
corollary 3.1. Theorem 3.
Under the hypotheses of Corollary 2.1, suppose that
hypothesis (2) is strengthened to (2.1)
Hn(C*/tC*)
is a free (A/tA)-module of rank one.
Then the left ideal
I
Corollary 2.1 is such that ~:
1.
described in conclusion (2) of I c: t • A.
The Note following Corollary 2.1 is equally appli-
cable to Theorem 3. 2.
Under the hypotheses of Theorem 3, conclusion (3) of
Corollary 2.1 is essentially equivalent to the conclusion of Theorem 3. Proof.
By conclusion (3) of Corollary 2.1, we have that
(3) as
Hn(C*/tC*) "" A/(I + tAl
(A/tA)-modules.
But by hypothesis (2.1) of Theorem 3,
n
(2.1)
H (C*/tC*) "" (A/tA)
as left (A/tA)-module.
Equations (3) and (2.1) imply that (A/tA) "" (A/ (I + tA» as left (A/tA)-modules, or equivalently that ideals in A. Corollary 3.1.
as left Q.E.D.
Under the hypotheses of Theorem 3, the following
five conditions are euqivalent. (1)
IctA,
as left A-module.
Chapter 6
676 (2)
(3)
(4)
d n - l = 0,
all integers
r
(a)
Hn(C*)~A/I
r> O.
as left A-module, where
left ideal contained in of and
(b)
I
is a
{t-divisible elements
A}.
u EA
a t-torsion element implies that
u
is t-
divisible (and therefore also infinitely t-divisible) in (5)
Let
J
A.
be the left ideal described in conclusion (1)
of Corollary 2.2. t-divisible. ments of
A}).
Then the left A-module
(Or, equivalently,
J
is
Jc: {t-divisible ele-
(Another equivalent condition:
J c: tAl .
When the five equivalent conditions of this Corollary hold, then necessarily
{t-torsion elements of
elements of
and therefore
A};
A} c:
{t-di visible
{t-torsion elements of
A}
is
a t-divisible left A-module. Note:
The Note following Corollary 2.1 is equally applicable
to Corollary 3.1. Proof:
By hypothesis (2.1) of Theorem 3,
free (A/tA)-module of rank one.
is a
Therefore conditions (1), (2) and
(3) of Corollary 3.1 are equivalent from the general theory of spectral sequences.
By conclusion (1) of Corollary 2.2, we have
that
En~ A/ (J + tAl 00 as left (A/tA)-module.
Therfore condition (1) of this Corollary
677
Highest Non-Vanishing Cohomology Group holds if and only if (5')
JCtA.
(5")
JC it-divisible elements of
If
then certainly (5') holds.
x=ts.y,
where
(1)
and
s >0
x
is not t-divisible.
~
of Corollary 2.2) .
yEA.
Therefore
tion.
Therefore every element of
holds.
Thus
(1)
y
E;
J.
Y It tAo
yEA,
(t S • y E J, s
the property that conclusion
Conversely suppose that (5') holds.
suppose that
x E J,
Then i f
A},
Since
But the ideal
0, yEA, But
t
J C tA, J
implies S
Then
s
~
has
(see
y E J)
.y=xEJ,
Y E tA,
J
0,
is a contradic-
is t-divisible, i.e.
(5")
(5' ) ~ (5") .
As noted in the footnote to conclusion (1) of Corollary 2.2, J=> it-torsion elements of holds,
A}.
Therefore, if condition (5")
it-torsion elements of
A} C it-divisible elements of
It follows readily that
it-torsion elements of
divisible left A-module.
A}
is a t-
This proves that the equivalent con-
ditions (1), (2), (3), (5') and (5")
all imply the observations
of the last paragraph of Corollary 3.1; and also that (5") condition ((4)(b».
If
(5")
holds, then since
(5"), we have condition ((4) (a».
ICJ,
Therefore (5")=> (4).
versely, assume that condition (4) holds, and let there exists an integer condition ((4)(a» yEA,
x
A}.
i >0
such that
is t-divisible.
x=t Since
and since every t-torsion element in
(by condition ((4) (b»), it follows that
i
y
yE J.
.yEI.
~
by ConThen Then by
x=ti.y, i>O, A
is t-divisible
is t-divisible.
678
Chapter 6
Therefore every element of holds.
(5")
holds.
is t-divisible, i.e. condition
J
Therefore (4)=(5").
Finally, suppose that (5")
Then we know that «4) (b»
holds, i.e. that every
t-torsion element is t-divisible. sible element in
A
is infinitely t-divisible, and therefore
that given any left ideal that
(t
s
It follows that every t-divi-
K
• y E K, s..:: 0, yEA,
in
A
(=
implies
left A-submodule) such
y E K) ,
contained in the t-divisible elements of sible as left A-module.
Therefore (5")
A
the ideal iff
I
is
K
is t-divi-
is equivalent to condi-
Hon (5). The two parenthetical parts of (5) are, repsectively, and (5').
(5")
Therefore the non-parenthetical part, and each of the
two parenthetical parts, of condition (5) are indeed equivalent, completing the proof of Corollary 3.1. Remarks: severe.
1.
Condition «4) (b»
of Corollary 3.1 seems rather
A more general situation is covered in the following
corollary. Corollary 3.1'. A' =
Under the hypotheses of Corollary 2.1, let
AI (t-torsion elements).
(I.e.,
A'
is the largest quotient
ring (or quotient left A-module) such that the image of non-zero divisor (or such that "multiplication by injective).
t
is a
t":A' +A'
is
Then the following several conditions are equivalent.
(1)
En 1'0 A' ItA' co
(2)
Hn(C*) ~A/I
ideal contained in
as left
AltA-modules.
as left A-modules, where
I
is a left
{topological t-torsion elements of I
image of
is contained in the t-divisible elements of
in
A'
A
(Or,
equivalently, where I
is a left ideal in
A}.
such that the
Highest Non-Vanishing Cohomology Group
679
A' .)
(3)
Let
J
be the left ideal in
(1) of Corollary 2.2.
of
A}.
A described in conclusion
Then JC {topological t-torsion elements
(Or, equivalently, the image of
in the t-divisible elements of When this is the case,
J~
J
in
A'
is contained
A'). {t-torsion elements in
A},
and
n H (C*/tC*) '" A/ (K + tA), where
K
ments in Note:
is a left ideal in
A
contained in
it-torsion ele-
A}.
The Note following Corollary 2.1 is equally applicable to
Corollary 3.1'. The proof is similar to that of Corollary 3.1, and is left as an exercise to the reader. 2.
Under the hypotheses of Corollary 2.1, we always have
that En", A/K 00 where tAo
K
is a
as
(A/tA) -module,
(uniquely determined) left ideal in
A
containing
Another condition equivalent to the three conditions of
Corollary 3.1' of Remark 1 is (4) Proof:
K ~ {t-torsion elements of
A} + tAo
From the isomorphism, deduced from the short exact se-
quence (*) of Theorem 2 of Chapter 1, n (A/tA) ~ [H (C*) Itt-torsion) ] '" E~, A
680
Chapter 6
we see that under the hypotheses of Corollary 2.1, we necessarily as (A/tA)-modules, then necessarily
have that, if
K::J {t-torsion elements in
A)} + tA.
Therefore condition (4) is
equivalent to condition (1) of Corollary 3.1' of Remark 1). 3. if
A
To what extent is Corollary 3.1' "best possible"? is a ring with identity,
any left ideal contained in A},
t E center of
A,
and if
Hn(C*) ""A/I, where
D*
n C
flat over
i~n+l,
Hi(C*) =0,
I
is
{topological t-torsion elements in
then does there exist a Z-indexed cochain complex
left A-modules, with each
I.e.,
A,
C*
of
such that
and such that
Hn(D*)""A'/tA',
is as in the parenthetical part of the Note to Corol-
lary 2.1; and where answer is "Yes".
A'
is defined as in Corollary 3.1'?
In fact, define
C+ l = A,
cO = A (10),
The
where
(x,) 'EI
is some set of generators for the ideal I, and del dO:CO .... C to be the map that maps the i'th element of the
110
fine
canonical basis of the left A-module, Define
C
i
= 0,
i 10,1.
Then
A (10)
all
into
n = +1,
and the reader
will verify the indicated assertions. 4. let
A
To what extent is Corollary 2.1 "best possible"? be a ring with identity, let
t E center of
A
I.e.,
be such
that every precise t-torsion element is t-divisible (it follows readily that every t-torsion element is infinitely t-divisible see the arguments near the end of Chapter 1), and let left ideal contained in can we find a
Z-indexed cochain complex
modules and an integer i ~n + 1,
it-divisible elements of
and such that
n
such that Hn(D*) "" A/tA,
C*
be any then
of flat left A-
Hn(C*) ""A/I, where
parenthetical part of the Note to Lemma I?
A},
I
D*
Hi(C*) =0, is as in the
The answer is again
Highest Non-vanishing Cohomology Group
681
"yes" and in fact the construction of Remark 3 above gives such a cochain complex 5.
C*
(such that
C
i
= 0,
i
1- 0,1)
with
= +1.
n
Suppose that the hypotheses of Corollary 3.1 hold, and
that the equivalent conditions hold, but that we are in the situation of the Note to Corollary 3.1. "multiplication by t": and replace "Hn(D*)"
c
i
-+
"Hi(C*/tC*)"
c
(I.e., we do not assume that
is injective, all integers
by
throughout, where
Lemma 1.)
i
"Hi(D*)", D*
and
i,
"Hn(C*/tC*)"
by
is defined as in the Note to
Let us also assume that hypothesis (3) of Proposition
2 is replaced by the weaker assumption hypothesis (3') of the Remark following Corollary 2.2. corollary 3.1 is that elements in A
A}.
Then one of the conclusions of
{t-torsion elements in
A}c{t-divisible
This is a strong condition on
A.
E.g.,
if
is a Noetherian commutative ring, then this implies (consider-
ing condition (3') of the Remark following Corollary 2.2) that t
is a non-zero divisor in
zero t-divisible elements in
A,
for the t-adic topology, since A
(Since there are then no non-
A.
since t
A
is then Hausdorff
is in the Jacobsen radical of
by hypothesis (3') «a) or (b»
of the Remark following Corol-
lary 2.2).
6.
At the other extreme of Theorem 3, Corollary 3.1 and
Corollary 3.2 is the following amusing observation.
Assume that
we have the hypotheses of Corollary 2.1, and let
be the left
ideal in conclusion (2) of Corollary 2.1. conditions are equivalent: integer
r >0
such that
(1)
t
r
En
E I.
00
=
En = 0 00
iff the element
I
Then the following (2)
There exists an
(More precisely, in fact, the
following conditions are equivalent: The proof:
o.
I
(lr)
E~
= 0;
(2r)
t
r
E I) .
n 1 E A/ (I + tAl = H (C*/tC*) = En
o
Chapter 6
682
n u E H (C*)
is a permanent boundary iff there exists an element mapping into a generator of the (A/tA)-module that
u
Hn(C*/tC*)
such
is a t-torsion element (this follows from the short
exact sequence (*) of Theorem 2 of Chapter 1). element
u (: Hn(C*),
by conclusion (4) of Corollary 2.1
a generator of the simply generated A-module Therefore such a
Given such an
n u E H (C*)
a t-torsion element,
3r ~ 0
(The equivalence of (lr)
is
Hn(C*/tC*) ~A/I.
exists iff the element
i. e., iff
u
such that
1 E A/I t
r
is
E I.
and (2r) is similar, with the short
exact sequence (*r) in the Remarks (Remark 3) following Theorem 2 of Chapter 1 replacing the short exact sequence (*) of Theorem 2 of Chapter 1). Theorem 4.
Let
the center of left A-modules.
A A.
be a ring with ide and let t be an elt. of Let
Let
C* n
be a
~
-indexed) cochain complex of
be a fixed integer.
Suppose that the
following technical conditions hold. Condition (1) of Lemma 1, Condition (3) of Lemma 1, and
Condition (3) of Proposition 2. Suppose also that
A
(E.g., this is the case if (since
t
has no infinitely t-divisible elements A
is a Noetherian commutative ring
is in the Jacobsen radical of
condition (3) of Proposition 2 holds,
A,
since by hypothesis
(the weaker condition (3')
of the Remark following Corollary 2.2 suffices for
this))~
Suppose also that (1)
Hi (C*/tC*) =0,
i~n+l,
and that
(2) Hn(C*/tC*)
is a free (A/tA)-module of rank one.
Highest Non-Vanishing Cohomology Group
683
Then
and where
(1)
Hi(C*) =0,
(2)
n H (C*) "" A/I
I
i .::. n + 1,
as left A-module,
is a left ideal in
uniquely determined).
A
contained in
tAo
(I
is
In addition, the following several condi-
tions are equivalent: (1)
and
(a)
t
is a non-zero divisor in
(b)
Hn(C*)
is a free A-module of rank one (An equiva-
lent form of
If
«l)~»:
conclusion (2) above, then (2)
En"" (A/tA)
(3)
E~ = E~
(4)
dn- l r
00
(1') Let
= 0, J
A.
as left
I
is the left ideal in I = {o}) •
(A/tA) -module
all integer
r> O.
be the left ideal in the ring
Corollary 2.2.
Then
J=
A
described in
{O}.
Also, when these equivalent conditions hold, A
has no non-
zero t-divisible elements. Notes: 1.
The technical condition, condition (1) of Lemma 1,
can be eliminated, if we assume that A,
t
is a non-zero divisor in
and if in conditions (1) and (2) of the Theorem, we replace
"Hi(C*/tC*)"
and
"Hn(C*/tC*)"
by the percohomology groups (see
the definition in the latter part of Chapter 5) and
"H~(A/tA,C*)"
respectively.
volving the cochain complex
D*,
"H!(A/tA,C*)"
(Also, an observation inas in the parenthetical obser-
vation in the Note to Lemma 1, can be made). 2.
Also, the technical conditions, condition (3) of Propo-
sition 2, and condition (3) of Lemma 1, can be weakened, respec-
Chapter 6
684
tively, to condition (3') of the Remark following Corollary 2.2, and to condition (3') of the Note to Lemma 1, if we replace conclusion (1) of this Theorem with" (1')
Hi(C*)
is at-divisible
left A-module, and has no non-zero t-torsion, all integers i~n+l",
and if we also weaken conclusion (2) of this Theorem,
by replacing
"Hn(C*)"
by
"Hn(C*)/(t-divisible elements)",
and also modify condition «1) (b» replacing 3.
"Hn(C*)"
by
of this Theorem, again by
"Hn(C*)/(t-divisible elements)".
Both the modifications indicated in Notes 1 and 2
above, in this Theorem, can be made simultaneously. Proof.
The hypotheses of Corollary 2.1 hold, and therefore we
have conclusions (1) and (2) of Corollary 2.1, which proves conclusion (1) and the first part of conclusion (2) of this Theorem. Also the hypotheses of Theorem 3 hold, and therefore the conclusion of Theorem 3, that
letA.
conclusion (2) of this Theorem.
This completes the proof of Since the hypotheses of Theorem
3 hold, the hypotheses of Corollary 3.1 also hold, and therefore we have that the five conditions, (1) - (5), of Corollary 3.1 are equivalent.
But, condition (2) of this Theorem is condition (1)
of Corollary 3.1; condition (3) of this Theorem is condition (2) of Corollary 3.1; condition (4) of this Theorem is condition (3) of Corollary 3.1.
Since by hypothesis the ring A has no infi-
nitely t-divisible elements, condition «4) (b» is equivalent to condition «1) (a» If condition «1) (a» sion elements.
of Corollary 3.1
of this Theorem.
holds, then A has no non-zero t-tor-
Therefore an element of
sible iff it is t-divisible.
A
is infinitely t-divi-
But by hypothesis, the ring
no non-zero infinitely t-divisible elements.
Therefore
A A
has
has
Highest Non-Vanishing Cohomology Group no non-zero t-divisible elements.
Thus, under condition «1) (a»
of this Theorem (equivalently condition «4) (b» 3.1) the ring
A
fore i f «1) (a»
685
of Corollary
has no non-zero t-divisible elements. of this Theorem (equivalently,
Corollary 3.1) holds, then condition «4) (a» holds iff condition «1) (b»
There-
«4) (b»
of
of Corollary 3.1
of this Theorem holds.
Therefore,
condition (1) of this Theorem is equivalent to condition (4) of Corollary 3.1.
Finally, note that condition (5) of Corollary
3.1 is equivalent to condition (I') of this Theorem (Proof: Obviously,
(I') of this Theorem implies (5) of Corollary 3.l.
Conversely, if condition (5) of Corollary 3.1 holds,then t-divisible as A-module. finitely t-divisible.
Therefore every element of
But by hypothesis,
infinitely t-divisible elements.
Therefore
A
J
is
is in-
J
has no non-zero J = 0;
Le., condi-
tion (5) of Corollary 3.1 implies condition (1') of this Theorem). Therefore, conditions (1), (2), (3), (4) and (I') of this Theorem are respectively equivalent to conditions (4), (1), (2), (3) and (5) of Corollary 3.1.
Therefore, by Corollary 3.1, conditions
(1), (2), (3), (4) add (I') of this Theorem are equivalent. Finally, we have observed that condition «1) (a» Theorem implies that the ring elements.
A
of this
has no non-zero t-divisible
Therefore the five equivalent conditions of this
Theorem all imply that the ring
A
has no non-zero t-divisible
elements. The proof of Note 2 is similar.
Q.E.D.
This Page Intentionally Left Blank
CHAPTER 7 POINCARE DUALITY
Recall the following two definitions: Definition 1.
Let
A
be a commutative ring with identity.
graded A-algebra is a sequence indexed by all the integers,
A n C ,
nEz, of A-modules, together with homomorphisms of A-modules: n n m C 0 em .... e + ,
called the multiplication (or sometimes the cup
A
product), all integers
n,m,
additive group of the A-module tion
C 0 C .... C A n,mEZ),
all
mutative).
(-1)
e
en @em .... e n +m, A is a ring with identity (but not necessarily com-
The graded A-algebra
n+mv U u,
is non-negative iff Definition 2.
e =
(deduced from the multiplications
skew commutative, iff u E en, uUv =
e en, then the nEz together with the multiplica-
such that if
Let
v E em
all integers e A
i
= 0,
e*
is anti-commutative, or implies that
n,m.
The graded A-algebra
all integers
i < O.
be a commutative ring with identity.
a differential graded A-algebra (abbreviation, "d.g.a. over or
"d.g.a")
is a graded A-algebra
morphisms of A-modules that v E em
n n d +l • d
= 0,
n d n : C .... e n + l ,
all integers
impl ies tha t
all integers
n,m. 687
n,
e*,
C*
together with homo-
all integers and such that
n,
such
u E en,
Then A"
Chapter 7
688
Of course, if
C*
is a differential graded A-algebra, then
is a graded A-algebra.
(Bh(C*))hEZ
Let us pose another definition.
Definition 3. let
C*
Let
A
be a commutative ring with identity and
be a graded A-algebra.
iff there exists an integer
n
Then
obeys Poincare duality
C*
such that conditions (PDl) and
(PD2) below hold.
(RD~)
For the fixed integer
n,
n C
we have that
is a
free A-module of rank one. For every integer
i,
i
i
¢ : C ... Bom (C
let
A
morphism of A-modules, that to every
n i
v EC -
I
phism that to every right" I
'l
and let
u EC
cp
and
all
A
vEC n - i .
tegers
alized:
= u u v,
be the A-homomoru
on the
Then
C*
over cpi
A
is skew-
= (_l)n
• '
¢i,
all
i,
so that (RU2) can be stated only for
all in-
2.
The definition of "Poincare duality" can be gener-
i.
we can weaken Axiom (RD2), by requiring only that
.
n
~ ~2
'
and that
This weaker axiom (equivalent if
"cpi
is an isomorphism C*
mutative) would suffice for Proposition 1 below. n
(u)] (v)
are isomorphisms of A-modules.
Of course, if the d.g.a.
is an isomorphism if if
i
the homomorphisms of A-modules,
commutative (as is usually the case), then integers
[¢
,
associates "cupping with
For every integer i, ,i i n-i n cp,: C ... Bom (C , c ), 1.
be the homo-
associates the A-
A
i
['cpi(u)](v)=vUu,
Remarks:
u
ll
n i Ci ... Bom (C - I en)
(RD2) i
i
u EC ,
homomorphism "cupping on the left with all
n-i , Cn )
is skew-com(Of course, if
is even, then the "weaker" axiom would agree with (p.n2) for
i =!!) • 2
Poincare Duali ty
689
Recall also Definition 4.
Let
A
commutative) and let module
M
be a ring with identity (not necessarily M
be a left A-module.
Then the left A-
is reflexive iff the natural homomorphism of left A-
modules: M -> HOm (Hom (M,A) ,A) Aright Aleft is an isomorphism. Example 1.
Let
A
be a principle ideal domain and let
finitely generated A-module. reflexive iff Example 2.
m
ring,
Let
C*
M
is
is locally free of finite rank (i.e., flat). A ==
i aim,
A==7L.,
are both reflexive.
Proposition 1. let
be a
a is a discrete valuation a, and i is any positive
where
Then every finitely generated A-module is reflexive.
Example 3. w
Let
Then it is easy to see that
is the maximal ideal of
integer.
7L.
M
M
Let
A
the ring of integers. (And, in fact,
Then
7L.(w)
and
Hom7L. (7L. (w) ,7L.) =.zw).
be a commutative ring with identity and
be a graded A-algebra that obeys Poincare duality.
Then (1)
For every integer
i,
(2)
If the graded algebra
the A-module C*
ci
is reflexive.
is non-negative, and if
is not the zero ring, then the integer
n
A
in the definition of
Poincare duality is uniquely determined, and in fact is the largest integer Proof: by axiom
j
such that
c j t- o.
Since the graded A-algebra
(P.Ol) for every integer
of A-modules:
C* i
obeys Poincare duality, we have the isomorphism
Chapter 7
690 cp
i
i
: C "" Hom (C
n-i
A
and similarly for
'cpi.
n ,C )
But by Axiom (P.D.l),
Cn""A
as A-module.
Therefore we have the isomorphisms cpi and ,cpi : Ci "" Hom (C n-i ,A) , all integers (3) A respectively. deduced from cpi and 'cpi, Cn - i
Applying this equation to
i,
and substituting into equation
(3), we have the composite isomorphism Hom (. cp n-i ,A) A
(4)
0
cp
i : Ci""-+ Hom (Hom (C i ,A) ,A) . A A
Checking the construction of the isomorphisms (3), we see that the isomorphism (4) is the natural mapping (from any A-module into its bidual), described in Definition 4. module
C
i
is reflexive, all integers
i.
Therefore the AThis proves equation
(1) •
Next, suppose that the graded A-algebra and that wi th
A
n - i < 0,
C
=
o.
i
Cn - i
= o.
i
C "" Hom (C A
and since the graded algebra
tive, i t follows that i
Then if
then by equations (3),
i > n,
i > n,
is not the zero ring.
C*
is non-negative is an integer
n-i C*
,A).
But since
is non-nega-
Therefore by equation (3) ,
That is C
Since
i
= 0,
all integers
en", A¥ 0
i > n.
as A-modules, conclusion (2) of the Propo-
sition follows. Remarks 1. we have
In all practical applications that I know of in which
C*
a graded A-algebra that obeys Poincare duality,
a commutative ring with identity), it is always true that (1)
The graded A-algebra
C*
is non-negative,
(A
691
Poincare Duality (2)
C
i
is finitely generated as A-module, all integers
i,
and
(3)
The graded A-algebra
C*
is anti-commutative.
However, of course, it is quite easy to construct an example of a graded A-algebra (e.g. with
A=Z)
that obeys Poincare duality
in the sense of Definition 3 above, yet violates all of the above three conditions.
E.g., one can use Example 3 following Defini-
tion 4 to construct such an example, with
n = 0:
ci=o,
and
if-l,O, or 1,
W
<j>: Z "" HOrrz (Z a:Zw+Z w
(w)
,Z)
CO=Z,
c-l=:?!:(w)
Define c+l=Zw.
Let
be the natural isomorphism, and let
be an automorphism of the abelian group
ZWf~l
(e.g.,
an automorphism arising from a non-trivial permutation of the factors, even one of infinite order.) uU v= (<j>(v»
Then
C*
(u),
and
Then define
v U u = <j> (a (v) ) (u) ,
all
uEC
-1
,
is a graded z-algebra obeying Poincare duality in the
sense of Definition 3, yet
C*
does not possess any of the
properties (1), (2) or (3) above. 2.
A generalization of Definitions 1,2, and 3 is possi-
ble, in which the assumption identity"
is replaced by:
"A "A
is a commutative ring with is a ring with identity".
E.g., in Definition 1, replace the phrase "A-module" by "abelian group" and replace
"®"
with
"®"
throughout.
And
A
add the hypothesis, that we are given a homomorphism of rings with identity:
A + cO.
The definitions of "skew-commutative", "non-negative" and Definition 2 ("differential graded A-algebra") then generalize without change. (Definition 3 can also be generalized to the case in which
692
Chapter 7
the ring with identity
A
is not commutative, and one then ob-
tains the generalization of Proposition 1.
However, such a gen-
eralization of Definition 3 makes it necessary to distinguish carefully between
"right" and "left"
Poincar~
duality.
There
are at the moment no known (or even forseeable) applications of such a generalization.
Therefore we choose not to pose such a
generalization of Definition 3.) Example 1.
Let
X
(respectively: over a field tic
2).
be a topological manifold that is orientable
that is not orientable). k
Let
(respectively: over a field
k
Then the usual singular cohomology
POincare duality as graded A-algebra. then if
A be an algebra of characteris-
H*(X,A)
Also, if
X
obeys
is orientable,
A is any ring without non-zero integer torsion (i.e.,
such that
and i f we define
ACA0~),
Ch=Hh(X,A)/(integer
Z
torsion)
(i.e., the image of
Hh(X,A)
in
Hh (X,A)
®~),
then
Z
the (non-negative, skew-commutative) graded A-algebra Poincare duality.
C*
obeys
(This observation follows readily from the
usual universal coefficients theorem of topology, and from Theorem 3 below.) 2.
Let
over a field
k.
X
be a complete, non-singular algebraic variety
Let
a finite algebraic field
extension of the field (1)
H*(X,r~),
k.
Then
the hypercohomology of
X
with coefficients
in the cochain complex of sheaves of differential forms over obeys Poincare duality as graded (2) nal prime
If
k
mology [<:N'JJ
ko-algebra.
is algebraically closed, and if
t- characteristic h
A
H (X,Zq)'
of h > o.
k,
k,
q
is a ratio-
then consider the q-adic cohoDefine
h
h
A
C = H (X,Zq) / (q-torsion) .
Poincar~
Duality
693
Then by Corollary 3.1 below, the graded
i-algebra
C*
q
obeys
Poincare duality. (3)
If
k
is of characteristic
pI- 0,
then let
0
be a
complete discrete valuation ring of mixed characteristic having k
for residue class field.
Let
Hh(X,O)
be the lifted p-adic
cohomology of X, "using the ~" as defined in [P.ACJ. Let h c = Hh (X, 0) / (p-torsion), all integers h> O. Then the (nonnegative, skew-commutative) graded Poincar~
duality.
O-algebra
C*
obeys
(The proof in [P.AC.] strongly uses Corollary
3 .1 below.) (4)
An observation similar to (3) above applies to our
p-adic cohomology using the bounded Witt vectors [BWY.]; the proof is similar. Let
3.
X
A
be a commutative ring with identity and let
be a scheme simple and proper over
then
B
is an etale covering of
(I)
If
A
A.
A.
0
Let
B=H (X,OX);
And,
is an algebra over a field of characteristic
zero, then The graded B-algebra H*(X,rA)-the hypercohomology of
(T)
X
with coefficients in the cochain complex of sheaves of differ-
ential forms over
A - obeys Poincare duality (over
B).
(A similar observation holds in the analytic case, where X
is simple and proper over a Stein manifold "r~",
replaces
covering of
A,
and where
A = r (Y, OY) }.
Y,
Again,
and observation (T) holds.)
and B
"ry"
is an etale
(In characteristic
zero, and also in the analytic case, this follows from the main theorems in [P.ACJ.) If
A
is an algebra over a field of characteristic
p" 0,
Chapter 7
694
A
and if
is a local ring, such that the p'th power of the maxi-
mal ideal of
is zero, then again by methods of [P..ACJ I can
A
(See [P.AJ:J).
prove conclusion (t)
(2) (i. e .,
If
A
is any commutative ring without integer torsion
such tha t
A
C
A Q q,; ) ,
then let
Z
C~Hh(X,rA}/(integer torsion) (i. e.,
the image of
Hh (X, r
A)
in
Hh (x,r ) ® IJ)} , A
all integers
Z
h.
Then the non-negative, skew-commutative, graded B-algebra
C*
obeys Poincare duality.
(3)
If
A
(~/pZ)-algebra,
is a
i-algebra
suppose that we have a X
p
where
A
cal condition of being embeddable over (e.g., it suffices that [1,
X
integers
~/\P-adic cohomology of h> O.
Then
cO
Poincar~
duality.
that obeys the techni-
~,
Let
in the sense of [P.AJ:J
ch =
Hh (X,~/\p) ,
X as defined in [P.N:J, all
is an etale covering of
(non-negative, skew-commutative) graded obeys
Let
be either projective or liftable over
(or else obeys weaker conditions}).
the lifted
is a prime, then
such that
A
be a scheme simple and proper over
p
~/\p,
cO QIJ)-algebra
and the C* ®IJ)
Z Z (This is proved in [EAJ:J, and makes use
of Theorem 3 below, and also of Theorem 1 of Chapter 5 of this book. )
(In the special case that the scheme
proper lifting over
~,
X admits a simple,
this was first proved in my seminar on
"Zeta Matrices" in 1969-1970, for which lecture notes will eventually be available.
A portion of that material appears in
[P.C.TJ ) . Suppose that we have a differential graded algebra over the commutative ring
A
that obeys
Poincar~
C*·
duality.
Then
Poincare Duality
695
when can we conclude that the cohomology
Hh(C*),
is a graded A-algebra, obeys Poincare duality?
hEZ,
which
A weak result
(although, see Example following Proposition 2, pretty close to best possible), is given in Theorem 2. that
A
Let
A
be a commutative ring with identity such
is injective as an A-module.
strong condition, cf.
Remarks below).
(Note: Let
This is a very C*
be a skew-
commutative differential graded A-algebra that obeys Poincare duali ty, and let
n
Definition 3 hold.
be an integer such that
O=~D.l)
and (P.D.2) of
Then condition (2) below implies condition
(1) :
The graded A-algebra
(1)
duality for the same integer (2)
(a)
then (b)
h Ez ,
obeys Poincare
n.
d n - l : Cn-l-+c n
If
in the d.g.a.
and
Hh (C*),
is the (n-1) 'st coboundary
(in fact, cochain complex)
C*,
dn-l=O.
l d- : c-l-+CO,
the (-1) 'st coboundary, is iden-
tically zero. If the d.g.a.
C*
should be non-negative (or weaker, if
n n n d : C ... C + l is the zero map), then conditions (1) and «2) (a» above are equivalent, and each is also equivalent to the following condition: (2') Proof:
Hh(C*)
is a free A-module of rank one.
First, we show that condition (2) implies condition (1).
For every A-module assignment:
M~>M*
M,
let
M* = Hom (M,A). Then the A is an additive, left-exact, contravariant
functor from the category of A-modules into itself, and since by hypothesis
A
is injective as A-module, we have that the
696
Chapter 7
contravariant functor: Let C*
is also an exact functor.
M~>M*
and
be an integer,
i
is a d.g.a.
vEC
n-i-l
Then, since
.
(Definition 2), we have
d n - l (u U v) = d i (u) U v + (-1) iu U (d n - i - l (v) ) . n d - l = O.
But by hypothesis (2),
Therefore, from the above
equation, we deduce that d i (u) U v = (-1) i+lu U d n - i - l (v) ,
(1)
v ~
cn - i - l
,
all integers
i
all
u EC ,
all
i.
By Axiom (ED.l) , we can fix an isomorphism of A-modules:
c
n
", A.
Identify the A-modules
fixed A-isomorphism.
n C
and
A
by means of this
cpi
Then the isomorphism
of Axiom (EU2)
is an isomorphism of A-modules
cpi: Ci ':;' (C n - i ) *,
(2) (d n - i - l ) *:
(C n - i ) *
-+-
all integers
(C n - i - l ) *
(Le. ,
dn- i - l
all integers
i.
(c] n-i-l) * = the
under the contravariant functor,
M~>M*),
Then I claim that the diagram
(C n - i ) *
(3)
Let
denote the transpose of the
A-homomorphism image of
L
(dn-i-ll*
>(C n - i - l )*
ai
CPil t ci
d
i >
,i+l
ci +l
of A-modules either commutes or anti-commutes, for each integer L
(More precisely, the diagram (3) commutes when i is odd,
and anticommutes when Proof.
Let
u E ci
i
is even.)
and let
l v E (C n - i - ).
Then
Poincare Ouality [(d n - i - l ) * (¢i (u»
697
1 (v)
(h .... [¢i (u) (d n - i - l (h»
1) (v)
n i l (h .... [u U d - - (h) 1) (v)
= u U (d
n-i-l
(v»,
while
d
i
(u) U v.
Therefore, considering equation (1), indeed the diagram (3) commutes (resp.:anticommutes) according as (resp.:
is even
odd). oi = (C n - i ) *
Therefore, if we let
all integers is a
i+l
and let i,
then
i i (0 ,0 liEd:
(d:-indexed) cochain complex of A-modules, and the sequence i (¢ ) iEZ
of A-homomorphisms
is a map - in fact, by Axiom (P.O.2),
an isomorphism - of (Z-indexed)-cochain complexes of A-modules: i (¢ )iE::.l
(C*,d*)"" (0*,0*).
Therefore we have the induced isomorphism on cohomology
all integers But since integers
i,
i. oi
=
(C n - i ) *,
and
the cochain complexes
oi
=
(-1) i+l (d n - i - l ) *,
(0*,0*)
all
and
have equal (not merely isomorphic, but equal) cohomology groups. equation (4) becomes an isomorphism
Therefore
698
Chapter 7
(5)
M~>M*
But since the functor
is exact, we have the canonical
isomorphism (6)
Hi(((C n - i )*,
(dn-i-l)*)iE.z)""Hi((Cn-i,dn-i-l)iE.z)*=
Hn-i(C*,d*)*, all integers
i.
The composite of the isomorphisms (5) and (6)
is an isomorphism of A-modules (7)
Hi(c*)~HOmA(Hn-i(C*)'A)'
NOw, since by hypothesis (d- l ) * = O.
have that .
~
= n,
((2) (b))
d
n-l
=d
n
= 0,
Cn""A
we therefore
n n d: C
-+
n+l C
n n. H (C*) = C. S~nce
whence
poincare duality for the integer we have that
d- l = 0,
From the commutative diagram (3) with
we deduce that the coboundary
But then
i.
all integers
n,
is zero. C*
obeys
by Axiom (P.U2) for
C*
as A-modules; and, in fact, earlier we have
identified the two by means of a fixed such isomorphism,
n C = A.
Therefore, (8)
Hn(C*)""A
as A-module.
This proves that the graded A-algebra Axiom (P.Ul) for the same integer (fixed) identification
n C =A
n.
Hi(C*),
i E.z,
obeys
Finally, substituting the
into equation (7) gives an iso-
morphism of A-modules:
If we trace the construction of the isomorphism (9), we see that it is the function that sends
u E Hi (C*)
into the A-homomorphism:
Poincar~
v+uUv, u").
all
vEHn-i(C*)
Therefore Axiom
Duality
(Le.,
699
"cupping on the left with
is verified, and we have proven
(P.D2)
that condition (2) implies condition (1). We have already observed, that if the d.g.a.
C*
(Proposition 1, conclusion (2)),
is non-negative, then the integer
n
such that (pnJ) and (ED2) hold is uniquely determined, and C i = 0, C*
all integers
i
such that
is non-negative, then
i > n.
n dn:C n +C + l
In particular, if
is the zero map, as
asserted parenthetically in the conclusions of Theorem 2.
To
complete the proof of the Theorem, we must show that if n n l n d : C +c +
is the zero map, then conditions (1), «2) (a)) and
(2') are equivalent. In fact, equations (1)-(7) in the proof of the first paragraph of the Theorem use only hypothesis «2) (a)) of the Theorem. Therefore, if «2) (a)) holds, then the diagram (3) is either commutative or anticommutative, all integers cular, for
i = n.
i,
and, in parti-
Therefore if condition «2) (a)) holds, then
By hypothesis, the d.g.a. over the commutative ring obeys
Poincar~
C
i
and in particular for ponds to
d
O CO"" (C )**.
that
d
-1
=
is a reflexive A-module, all integers i =-1
and
i = 0.
iff
we have seen that
l (d- ) ** =
(d- l ) * = 0.
d-
iff
l
C- "" (C- l )**,
l (d- ) = 0.
It follows
But, if condition «2) (a)) holds,
(d-l)*=O
tion «2)(a)) holds, then
°
i,
cores-
But
under the natural isomorphisms: Therefore
°
C*,
duality, and therefore by Proposition 1, part
(1), we have that
-1
A,
Therefore, if condi-
iff l
=
°
iff
Hence, if
Chapter 7
700
then condition «2) (a)) implies condition «2) (b)).
Otherwise
stated: (10)
If
d n = 0,
then condition (2) is equivalent to
condition «2) (a)) . We have already seen that condition
(2)~condition
Obviously condition (1) implies condition (2').
(1).
Therefore, con-
sidering equation (10), to show that, under the hypothesis, "dn=O",
that conditions (1),
it remains to show that: "dn=O",
«2) (a)) and (2') are equivalent,
condition (2'), and the hypothesis
imply condition (2).
In fact, if
n n-l H (C*) = Coker (d ),
then
n C .
A-module of the free A-module of rank one
a quotient
A quotient module
of a free module of rank one is free of rank one iff the submodule that one divides by is the zero submodule. HnCC*)
is a free A-module of rank one iff
n l d - = O.
n
"d = 0",
That is, under the hypothesis
(2') holds iff condition «2) (a)) holds.
Example 1.
iff
condition
This observation, and
equation (10) above, completes the proof that, if conditions (1),
Therefore
n Im(d - l ) = 0
d
n
= 0,
«2) (a)) and (2') are equivalent.
Let
A
be a field.
Then
A
then Q.E.D.
is injective as
A-module, and therefore the key hypothesis of Theorem 2 holds. Example 2.
0
Let
maximal ideal of
be a discrete valuation ring, let 0,
Then the quotient ring
and let A = O/M
m
m
M be the
be a non-negative integer. is injective as A-module, so
again the key hypothesis of Theorem 2 is obeyed by such a commutative ring
A.
It is also not difficult to describe quotient rings of
Poincare Duality regular local rings of dimension
> 2
701
that are injective as
modules over themselves. However, as we have observed prior to Theorem 2,
Remark 1.
the hypothesis in Theorem 2 that is extremely restrictive. is so).
"A
(Of course, if
A
is a field this
But most commutative rings with identity do not have
this property. Can the hypothesis A-module" be eliminated? A
is injective as A-module"
"A is injective as left
The following counterexample, in which
is a discrete valuation ring (this is about the "simplest"
case not covered by Theorem 2) shows that such is not the case (even if
C*
Example 3. field.
is non-negative). Let
Let
~
A=O,
a discrete valuation ring that is not a
be the residue class field of
a generator of the maximal ideal of
0
and let
s
be
O.
l
Define cO = 0, C = free O-module of rank 1 with basis 2 3 {x}, C = free O-module of rank 2 with basis {h,k}, C = free O-module of rank 1 with basis one with basis
{u}
i C* = (C ) i~
Make
and into a
{z},
ci=o,
4 C = free
all integers
(non-negative) graded
O-module of rank
i~O,1,2,3,4. O-algebra by
requiring that 1 E cO x
2
=h
be a two-sided multiplicative unit,
2
=k
2
= z
2
= xh = hx = xk = kx =
hz = zh = kz = zk = 0, xz = - zx = kh = hk = u. Then
C*
is a skew-commutative non-negative graded
and we see that the graded Define
i d : Ci
-+
i l C +
O-algebra
C*
O-algebra,
obeys Poincare duality.
to be the unique homomorphism of
O-modules,
702
Chapter 7
each integer d
i.:: 0,
such that
o = d 3 = 0,
dl(x) = s • h,
d 2 (h) = 0, d 2 (k) = s • z.
and
(Thus, necessarily or
i.::3.)
a-algebra
d
i
all integers
= 0,
Then the reader will C*,
i+l i dOd
together with the coboundaries
all
i <0
i d ,
iEZ,
thus
a-algebra
(I.e. , (C*,d*). '+ ' 1 i, and that d J (u U v)
, all lntegers
= 0,
di(u)Uv+(-UiuUdj(v), Note that, by
such that
verify easily that the graded
defined, is a differential graded that
i
i,jEz,
all
i
u E C,
all
a-linearity, it suffices to verify these identi-
ties for elements of
{l,x,h,k,z,u}).
Thus, all the hypotheses of Theorem 2 above, except the hypothesis that A
is injective as A-module, hold, for the d.g.a.
C*
A = 0,
(2 ')
over the ring -
with
and also the condition
n = 4. "d
n
Also, conditions (2) and
= O"--hold.
But, if we com-
pute cohomology, we see that O H (C*) "" 0,
Hl(C*) =0, 2 H (C*)""Ik,
H3 (C*) "" k, H4 (C*) ""
and of course 3 H (C*)
a,
Hi(C*) =0,
i<-l
are not reflexive as
or
i>5.
Thus,
H2 (C*)
and
a-modules, and therefore, by Propo-
sition 1, part (1), the (skew-commutative, non-negative) graded
Poincar~
Duality
703
does not obey Poincare duality over
O.
Therefore, although conditions (2) and (2') - and the condition "d
n
=
0",
and the condition
"C*
is non-negative" - all hold,
condition (1) of Theorem 2 fails. "A
is injective as A-module" in Theorem 2 cannot be deleted
(even in the case that Remark 2.
A is a discrete valuation ring).
Suppose that all of the hypotheses of Theorem 2 hold
for a given d.g.a. tity
Therefore, the hypothesis
C*
over a given commutative ring with iden-
(including the condition that
A,
A-module).
A
is injective as
Suppose also that conditions (1), (2), and (2') of
Theorem 2 hold.
Thus,
C*
obeys Poincare duality over
A,
and
so does the d.g.a. i If each c is projective finitely generated (*) as A-module, all integers by the A-modules
i E:Z, Hi (C*) ,
then is the same property inherited i E Z?
(Of course, this is the case if every A-module is projective.)
A
is a field, since then
But, the following example shows m A=O/M ,
that this is not the case, even if
m~2,
(the ring
(*) I f A is a commutative ring with identity, and if M is an A-module, then the following three conditions are equivalent: (1) M is projective and finitely generated as A-module.
(2)
M
is flat and of finite presentation as A-module.
(3)
The quasicoherent sheaf M over the topological space Spec (A) of 0Spec(A) -modules over Spec(A) is locally free of finite (not necessarily constant) rank.
'"
704
Chapter 7
of Example 2), the quotient of a discrete valuation ring not a field by any positive integral power greater than or equal to two of the maximal ideal and
C*
(Again, this
is non-negative.
is in a sense a "simplest" possible case, such that jective as A-module, but Example 4.
Let
a
M of
Then
A
a.
is in-
A is not a field).
be any complete discrete valuation ring that
is not a field and let ideal
A
Let
sea m
be any generator of the maximal
be any integer
> 2
and let
A = a/Mm.
is injective as left A-module.
Let
(~d*)
be the skew-commutative, non-negative differen-
tial graded a-algebra constructed in Example 3 above. (Example 3), we have seen that the graded poincare duality (with
n = 4).
a-algebra
Then, C* obeys
Define
Then again it is easy to see that the (skew-commutative, nonm negative) d.g.a. c; over the ring A=a/M obeys Poincare duality.
It follows that all the hypotheses of Theorem 2 hold
for the d. g. a. negative and (since
C*
c;
A = a/Mm.
Since
n - l ( =d 3 ). Cn - l ( =c 3 ) ~Cn( =C 4 ) dm m· m m m m of Example 3 is non-negative and
definition zero), 2 holds.
over the ring
c;
is non-
is the zero map d\
c 3 ~ C4
is by
we have also that condition (2) of Theorem
It follows from Theorem 2 that the conditions (1), (2)
and (2') of Theorem 2 all hold.
In particular,
(condition (1»),
the (skew-commutative, non-negative) graded A-algebra
(Hi(C;»iE~
obeys Poincare duality over
conclusion (1) of Proposition 1) ule, all integers
i E:
~.
Hi(C*) m
Nevertheless,
A
- and therefore (by
is reflexive as A-modHiCC*) m
is not projec-
Duality
Poincar~
tive as A-module, for
705
i = 1,2,3.
In fact, by explicit computation, we have that
H2
(C~)
'"
~
H3
(C~)
'"
k,
Ell k,
m H4 (C*) '" A( = O/M ),
and
m
and of course reflexive as
Hi (C*) m = 0,
i < -lor
i> 5 .
Of course
is
D<
A( =O/Mm)-module, but is not projective as A-module.
Thus, under the hypotheses of Theorem 2, even if conditions Ci
is
projective and finitely generated as A-module, all integers
i,
(1), (2) and (2') all hold, and
the same need not be true for if and
A = O/Mm, m
0
is non-negative, if
all integers
Hi(C*),
i
(even
is a discrete valuation ring not a field,
is any fixed positive integer :: 2).
Theorem 3. t
where
C*
Let
A
be a commutative ring with identity and let
be a non-zero divisor in the ring
A.
Let
C*
be a differ-
ential graded A-algebra such that (1)
A
is t-adically complete, and
complete, all integers (2)
Hi(C*)
all integers
C
i
is t-adically
i,
has no non-zero t-divisible, t-torsion elements,
i.
(E.g., by Theorem 1 of Chapter 5, condition (2) holds if the ring
A
is Noetherian, and if
era ted as A/tA-module,all integers (3)
Hi (C*/tC*)
is finitely gen-
i.)
The endomorphism "multiplication by
t": Ci +C i
Chapter 7
706
is injective, for every integer
i.
Suppose also that (4)
The ring
A/tA
(This
is injective as (A/tA)-module.
is a very strong condition, see Examples 1 and 2, and Remark I, following Theorem 2.
This hypothesis in essence cannot be elim-
inated, however, see Remark 6 following the proof of this theorem), and that (5)
The graded (A/tA) -algebra
negative, skew-commutative and obeys n
be an integer
Hi (C* /tC*), i E z, duality.
Poincar~
is nonThen let
such that Axioms (EUl) and (pn2) hold for the
graded (A/tA)-algebra in (5). Assume also that (6)
The image of
Hi(C*/tc*)
{t-torsion elements in
Hi(C*)}
in
is finitely generated as (A/tA)-module, all integers
i.
Then the following eight conditions are equivalent: (1)
The graded A-algebra i E z,
Hi (C*) / (topological t-torsion),
obeys Poincare duality, for the same integer (2)
n.
Hn(C*)/(t-divisible elements) is a free A-module of
rank one. (2 ') that
a c A,
a' x
t-di visible for all
n x E H (C*) ,
implies
a = O. (3)
Hn(C*)/(topological t-torsion)
is a free A-module of
rank one. (3 ') Hn(C*)
a E A,
for all
a· x
a topological t-torsion element in
xcHn(C*),
implies that
a=O.
Poincare Duality (4) Let
(E;,d;)iE7
707
be the generalized Bockstein spectral
r>O sequence of the cochain complex of A-modules to the endomorphism, "multiplication by ter 1.
C*
with respect
t", as defined in Chap-
Then l - 0 dn r ,
If
(4')
i
all integers i
(Er,dr)iEz
r >
o.
is the generalized Bockstein as in
r>O condition (4), the
E~
(4")
Eg =E~
is a free (A/tA)-module of rank one.
When this is the case, every topological t-torsion element in
Hn(C*)
is t-divisible (and therefore also infinitely t-
divisible) . Notes:
Hypothesis (3) can be dropped, if instead we modify
1.
the hypothesis (5) by replacing
with
(the percohomology groups of the cochain complex
"H! (C* ,A/tA)", of A-modules
"Hi(C*/tC*)"
C*
with coefficients in the A-module
A/tA,
as
defined in the latter part of Chapter 5). 2. (1')
Hypothesis (1) can be replaced by either condition
or (1") (1')
A
t-torsion) (1")
is t-adically complete and
Hi(C*)/(tOPolOgical
is t-adically complete, all integers t
i.
is in the Jacobsen radical of the ring
A,
A
has
no non-zero infinitely t-divisible elements and Hi(C*)/(topological t-torsion) is finitely generated as A-module, all integers
i.
(Hypothesis
(1) implies (1') of this Note, by Theorem 1 of Chapter
4.
In
708
Chapter 7
fact by Theorem 6 of Chapter
4, hypothesis (1) even implies
Hi (C*)/)t-divisible elements) is t-adically complete for
that
i).
all integers Remarks:
1.
If
is t-adically complete, then
A
Hi(C*)/topo-
logical t-torsion) is finitely generated as A-module (and there-
is finitely generated as
for complete) iff
This is because the former,
® (A/tA),
A/tA- module.
is the latter.
The proof
A
is by the method of proof of conclusion (4) of Proposition 2 of Chapter 6. 2.
In all practical applications of this Theorem
that I know, hypothesis (1") of this Note holds - but there are such "practical" applications when hypothesis (1) of the Theorem fails (see the Corollarly below)). Proof:
Obviously, condition
(3)~condition
tion (3)
(3').
(since i f
(2'), and condition
(2)~(condition
Clearly also, condition (2) implies condi[Hn(C*)/(t-divisible elements)]
is a free
A-module of rank one, then the t-divisible part and topological t-torsion part of
Hn(C*)
Next, let us show that
clearly coincide.) (3)~(2).
M=Hn(C*)/(t-divisible elements). that
Suppose (3).
Let
Then condition (3) tells us
M/(topological t-torsion) is a free A-module of rank one.
Since a free A-module of rank one is a projective A-module, and since
M/(topological t-torsion) is a quotient module of
follows that (1)
A
is a direct summand of
M,
i.e.,
M,
it
that
n H (C*) / (t-divisible elements) "" A E9 N
as A-module, where
N
is some A-module.
By hypothesis (5) of
this Theorem, and conclusion (2) of Proposition 1, we have that
Poincare Duality
709
hypotheses (1) and (2) of Lemma 1 of Chapter (2) of this Theorem (for
i=n)
Note 1 to Lemma 1 of Chapter
6 hold.
Hypothesis
implies hypothesis (3') of
6.
Therefore all the hypotheses
of Lemma 1, as modified by Note 1, of Chapter
6, hold, and
therefore so do the conclusions of that Lemma, in particular conclusion (5). (2)
Hn(C*)
That is, @
(A/tA) "" Hn(C*/tC*)
as
(A/tA)-module.
A
By hypothesis (5) of this Theorem and Axiom (P.Ul), we have that n H (C* /tC*) "" A/tA
as
(A/tA) -module.
Tensoring equation (1) above over
A
with
A/tA,
and substi-
tuting equation (2) and our last observation, we see that (A/tA) Ell (N/tN) "" (A/tA) as
(A/tA) -module.
It follows that
stated that the A-module (1),
N
N
N/tN = 0,
is t-divisible.
or otherwise But by equation
is isomorphic to a sub-module of an A-module that has
no non-zero t-divisible elements.
Therefore
N = O.
Returning
to equation (1), we see that Hn(C*)/(t-divisible elements) "" A as A-module, which proves condition (2). Thus, conditions (2), (2'), (3) and (3') are all equivalent. (Notice also, in the proof that
(3)~(2)
just given, that we
have observed that, when these conditions hold, that {topological t-torsion elements in
Hn(C*)} = {t-divisible elements in
Hn(C*)}.
This proves the statement in the last paragraph of the Theorem.)
710
Chapter 7 Also, by hypothesis (5), and by conclusion (2) of Proposi-
tion 1, we have that cular for
i=n+l.
Hi (C*/tC*) = 0
for
Therefore
i
~n + 1,
and in parti-
Therefore, from the
general theory of spectral sequences, it follows that for all integers
r >0
(4') are equivalent.
E~=E~.
iff
Also, since
I.e., conditions (4) and
En = Hn(C*/tC*)
is a free
o
(A/tA)-module of rank one condtions (4') and (4") are obviously equivalent. Next, let us show that condition (4") implies condition (3).
In fact, by hypothesis (2) for
i = n + 1, and by the short
exact sequence (*) in the conclusion of Theorem 2 of Chapter 1, we have that
[Hn(C*)/(t-torsion)] 0 (A/tA)""E n . A
En"" A/tA.
(4"1 tells us that
But condition
00
Therefore
00
n [H (C*) / (t-torsion) ] 0 (A/tA) "" (A/tA) , A
or equivalently, if we let (30) R=Hn(C*)/(topological t-torsion) then
(3)
R 0 (A/tA) "" (A/tA) A
as
(A/tA)-module.
But, by hypotheses (I') or (1") of Note 2,
we have therefore that
R
is simply generated as A-module.
(The argument is as follows: that image of module.
u
in
choose any element
R! (A/tA)
as A-module). (4)
such
generates this latter (A/tA)-
Then, by the argument used in the proof of conclusion
(4) of Proposition 2 of Chapter R
u ER
R", A/J
That is
6, we see that
u
generates
Poincar~
as A-module, where
J
(3) and (4) imply that
Duality
711
is an ideal in the ring J + tA = tA,
i.e.
A.
Equations
that
Jc tAo
(5)
But considering the definition, equation (30)' of the A-module R,
we also have that
R
has no non-zero t-torsion; substituting
this into equation (4) yields (6)
xEA,
txEJ=xEJ.
Next, I claim that the ideal t-divisible.
In fact, let
exists
such that
ye J. (1)
yEA Thus,
J
J, x E J.
x=ty.
considered as A-module, is Then, by equation (5), there But then, by equation (6),
is t-divisible, as asserted.
(or (1') or (1") of Note 2) imply that
A
But hypothesis is t-adically
complete (or, respectively, t-adically complete, or without nonzero infinitely t-divisible elements). ring
A
fore
J = O.
Thus, in all cases, the
has no non-zero infinitely t-divisible elements.
There-
Returning to equations (3 ) and (4), it follows 0
that n H (C*) / (topological t-torsion) '" A as A-module, i.e., that condition (3) holds. (4") implies condition (3), as asserted. dition (1)
Thus, condition
Also, obviously, con-
(considering Axiom (pn.l») implies condition (3).
Therefore, (2)-=- (2' )-=- (3)-=- (3' ) ,
in which case the last
paragraph of the conclusions of the Theorem hold;
712
Chapter 7 (4)~
(4')<:=:> (4") ;
(4")=(3),
and
(1)=(3).
Therefore, to complete the proof of the Theorem, it suffices to show that condition (2) implies conditions (1) and (4).
But
the hypotheses of Theorem 4, as modified by Note 2, of Chapter 6
then hold.
of Chapter
Therefore, by Theorem 4 (as modified by Note 2)
6, we have that the conditions (1), (2), (3), (4) and
(1') stated in the conclusion of Theorem 4 (as modified by Note 2) of Chapter
6 are equivalent.
But ((1) (a)) of VI.4
is true by the hypotheses of this Theorem, and ((1) (b)) of VI.4 (as modified by Note 2 to VI.4) holds by condo Hence condo
(1) of VI.4
(2) of this Thm.
(as mod. by Note 2 of VI.4) holds, and
therefore so do conditions (2), (3), (4) and (1') of VI.4.
But
condition (4) of VI.4 is the same as condition (4) of this Theorem.
Thus, condition (2) of this Theorem implies condition (4). Therefore, to complete the proof of this Theorem, it suf-
fices to show that condition (2) implies condition (1). We have already established that condition (2) implies conditions (2'),(3),(3'),(4),(4') and (4"). holds, Le.,
d n- l = 0 r
'
all integers
r >
In particular,
o.
Thus, by hypothesis (5), the graded (A/tA)-algebra i E:l, . ~nteger
(4)
Hi(C*),
is non-negative and obeys Poincare duality (for the fixed ) n.
But
E~O' = Hi (C*).
Th us,
( EO' i d i0 ) iE:l'
is a differ-
ential graded A-algebra, and by hypothesis (5) of this Theorem and by condition (4) with
r = 0,
we have that the hypotheses
of Theorem 2 hold, and that condition (2) of Theorem 2 holds. Therefore, by Theorem 2, the condition (1) of Theorem 2 holds, i.e., the cohomology of the differential graded (A/tA)-algebra
713
-Poincare Ouality i
i
(EO,dO)iEZ
obeys Poincare duality for the same integer
cohomology of this cochain complex is graded
(A/tA)-algebra n.
induction on
we see that
(7)
r,
Poincar~
duality for
Proceeding in this way using Theorem 2 by
For every non-negative integer r,
graded (A/tA)-algebra the fixed integer
The
thus, the
obeys
the same integer
n.
i EZ,
the (non-negative)
obeys Poincare duality (for
n).
Next, hypothesis (6) of the Theorem tells us, after considering Cor. 1.1 of Chapter 1, that for each integer i, is finitely generated as
(A/tA)-module.
Boo(E~l
i
But
i
B (EO) = U B (EO). r>O r there exists a positive integer 00
Therefore, for each integer r = r (i),
r
depending on
i,
be any integer ':'r(i)
o 2. i
2. n.
i,
such that
Let
for all integers
i
such that
Then,
for all integers
i
(since
i>n+l
if
or i f
i2.- 1 ).
But then
all integers (8)
i.
Considering equation (7), if follows that
obeys Poincare duality (for the same fixed integer Now, let Then
i E z,
The (non-negative) graded (A/tAl-algebra n).
oi=Hi(C*)/(topological t-torsion).
i E Z,
is a graded A-algebra.
To prove condition (1)
(and therefore complete the proof of the Theorem), we must show that the graded A-algebra
oi,
i EZ,
obeys Poincare duality,
714
Chapter 7
for the integer
n
described in hypothesis (S).
dition (3) implies (PDl). n
In fact, con-
It remains to prove (P.Q2).
I.e., let
be the map described in the statement of
Axiom (P.D2); then we must show that First, notice that
Di
is an isomorphism.
has no non-zero t-divisible elements,
and also no non-zero t-torsion elements, and that we have an isomorphism of graded (A/tA)-modules, (9)
i D ,
(In fact, considering the definition of
Di
has no non-
zero topological t-torsion elements, and therefore also has no non-zero t-divisible elements.
On the other hand, considering
the short exact sequence (*) in Theorem 2 of Chapter I, and hypothesis (2) of this Theorem, we deduce equation (9)). an integer
i.
Then
is one-to-one:
In fact, let
n i,
v ED -
Then, for every
we have
tion (9), it follows that, if then
uUv = 0
that
u=O.
that
t
for all
-
n-i
v E Eoo
u E Di uUv
Considering egua-
= O.
u
is the image of
•
By equation (a), it follows
Then
• U
divides
I,
u
in
Considering equation (9), it is equivalent to say u.
zero t-divisible elements. u = t
be such that
We have seen, preceding equation (9), that
j
Fix
where
j ~ 0,
Therefore, i f and
u' E Di
0=
u
Di
~ 0,
has no non-
we can write i u' ii! t • D .
is such that Since
dn- i
has no
non-zero t-torsion elements (by the observation preceding equation (9)), it follows that ceding paragraph applied to
¢i (u') = O. u',
But then, by the pre-
it follows that
tlu'
in
Poincar~
a contradiction.
Duality
Therefore if
¢
i
715
(u) = 0
then
u = 0,
as
asserted.
pi
is onto:
Identify the A-modules
condition (3). Rom (0 A
n-i
,A).
Then
n-i
RomA(O
Also, identify
n ,D) oi
on
and
A
by means of
is identified to
~ (A/tA)
and
E!
by means
A
of equation (9).
And also identify
Rn(C*/tC*)
with
A/tA,
using «RU1) of) equation (8). Let
v E RomA (0
phism, call it
v,
n-i
,A).
Then
v
induces an (A/tA) -homomor-
on-i ~ (A/tA)
from
into
A/tA.
Considering
A
equation (9), we see that n-i RomA/tA(E", ,A/tA).
v
By (RO.2) of) equation (8), there exists an
such that
element such that
is an element of
v(w) =uJw,
v = cupping on the left with
WEE~-i).
all
there exists an element
u E oi
(Le. ,
u
But, by equation (9),
such that
u
is the image of
Then, from the commutative diagram:
u
qJ
oi
(10)
;>
Jp
.J
01/tOi
/I Ei '" we see that
Rom (0 n-i ,A) A
;>
Rom / tA (0 A
n-i
/to
n-i
, A/tA)
II
u .... ( cu1212 in g: on the> n-i RomA/tA(E", ,A/tA), left with u)
and
v
Rom / (0 n-i /to n-i ,A/tA) . A tA
both map into the same element in But since the element
is a
tEA
non-zero divisor, the kernel of the natural homomorphism P: Rom (0
A
(Proof: in
n-i , A) .... Rom / (0 n-i /to n-i , A/tA) A tA If
f:On-i .... A
is zero, all
t · Rom (0 n-i , A) . A
is an A-homomorphism that maps into zero
RomA(On-i/tOn-i,A/tA) n i xEO - ,
is
then the image of
Le.,
tlf(x)
for all
f(x)
in
xEA/tA.
A/tA Since
716
t
Chapter 7 is a non-zero divisor in
g (x)
=f
xE on-i.
Thus, since
t . g = f).
under
all
(x)/t,
we then can define
Then
i
¢ (u)
g E Hom (0 A
and
v
n-i
,A)
and
map into the same element
i
i t follows that
p,
A,
tl (¢ (u) - v)
in
Hom (0 A
n-i
,A).
We
have shown that Every element of
(11)
t,
Hom (0 A
n-i
to an element in the A-submodule To complete the proof that
cpi
,A) 1m ¢
is congruent, modulo i
.
is surjective, we divide
into cases. Hypothesis (1" ) of Note 2 holds.
Case l.
on-i
Then
is
finitely generated as A-module, and therefore so is Hom (0 A
n-i
,A) .
Since (by hypothesis (1") of Note 2)
Jacobsen radical of
A,
is in the
t
equation (11) and Nakayama's Lemma MornA (0
n-i
,A)
(applied to the finitely generated A-module Im(¢i) complete the proof. Case 2.
Hypothesis (l'l of the Theorem holds.
is t-adically complete.
Therefore so is
Then
Hom (0 n-i ,A) A
a closed A-submodule of the t-adically complete A-module By hypothesis (I'), we have also that plete.
i
Therefore Im(¢ ),
oi
A
(being n-i AD
).
is t-adically com-
being the image of a homomorphism of
t-adically complete A-modules, is also t-adically complete.
But
then equation (II), and the argument in the proof of conclusion (4) of Proposi tion 2 of Chapter
HomA(O
n-i
6,
shows that
1m ¢ i =
,A).
The proof of Note 1 is similar.
Q.E.D.
Remarks 1.
The hypothesis (6) in Theorem 3 is unnecessarily re-
strictive.
In fact, the proof only required that we assume that,
Poincar~
for each integer
i,
717
there exists an integer
every t-torsion element in some
Duality
Hi(C*)
tr-torsion element of
r,
such that
is congruent, modulo
Hi(C*).
t,
to
In fact, a more penetrating
analysis can be made to show that hypothesis (6) can, in fact, be entirely eliminated.
(One starts by showing, by careful con-
sideration of exact sequences, using the fact that jective as
and
A/tA-module, that
ive as (A/tA)-modules, all integers 2.
A/tA
i,s,r
is in-
are reflexwith
s
~
0,
r
~
0).
The portion of hypothesis (5) of Theorem 3, that the
graded A/tA-algebra weay.er hypotheses.
Hi (C*/tC*)
is positive, can be replaced by
(A similar, obvious, observation can be made
in certain other theorems in this chapter). 3. which
Another generalization of Theorem 3 is possible, in
hypothesis (4) is eliminated, and (4") is replaced by:
"E~"" A/ (topological t-torsion)". that the element
One then removes the hypothesis
tEA is a non-zero divisor, and that
A has no
non-zero t-divisible elements, and e.g., in condition (1), one replaces the phrase where
"graded A-algebra" by "graded A '-algebra",
A' = A/ (topological t-torsion).
in conditions (2), (2'), (3), (3')
Similar changes are made
(replacing
A
by
A').
The re-
sulting, more generally applicable, theorem, is in the same relation to Theorem 3, as Corollary 3.1' of Chapter 6 1 following the proof of Corollary 3.1 of Chapter Corollary 3.1 of Chapter
6.
(in Remark 6) is to
We leave it to the interested
reader to write down such a "Theorem 3'''. 4.
Notice that, under the hypotheses of Theorem 3, but
not necessarily assuming hypothesis (6), we still have that conditions (2), (2'), (3), (3'), (4), (4') and (4")
are equivalent, and
Chapter 7
718
that all of these imply that, for each integer i >0
(A/tA)-algebra:
obeys
Poincar~
r,
the graded
duality for the same
(It is easy to see that, conversely, this latter
integer n.
condition implies e.g. condition (4».
And, if hypothesis (6)
also holds, then the equivalent conditions (1), (2), (2'), (3), (3'), (4), (4'), (4") all imply that the graded (A/tA)-algebra i E 1l ,
obeys
duality.
Poincar~
(And, conversely, whether or
not condition (6) holds, this latter condition implies (1), (2), ( 2 ' ) , (3) , (3' ) , (4) , (4') and ( 4 ") diately.
Then (4)=:>(2),
just observed. (2)=:> (1) i E 1l,
.
Proof:
(4) follows imme-
(2'), (3), (3'), (4') and (4") as we have
Finally, the latter part of the proof that
when hypothesis (6) holds also shows that if
obeys Poincare duality for the integer
n,
then condi-
tion (1) holds). 5. that
Suppose that condition (1) of Theorem 3 holds, and
Hi(C*)/toP010gical t-torsion)
A-module, all integers of the commutative ring element (1' )
t.
i. A
Let
is finitely generated as
A[t- l ]
denote the localization
at the positive powers of the
Then it is trivial to see that
The graded l ®A[t- ]
A[t
-1
]-algebra:
[Hi(C*)/(tOP010gical t-torsion]
obeys Poincare duality.
A
Conversely, under the hypotheses of Theorem 3, if condition (1') holds, then so also do conditions (1), (2), (2'), (3), (3'), (4), (4'), and (4"). Proof:
Let
Hn(C*/tC*) one.
n u E H (C*)
be such that the image of
u
in
is a generator of this free (A/tA)-module of rank
Then condition (1') implies that the A-submodule of
Poincare Duality
719
n M = H (C*) I (topological t-torsion) generated by rank one.
The proof that
u
is free of
follows readily by the
(l')~(3)
methods of the earlier part of the proof of Theorem 3.
(And
resembles the proof of Theorem 4 of Chapter 6). 6.
Theorem 3 above has one very restrictive hypothesis-
namely that
AltA
is injective as
that rarely holds.
(A/tA)-module, a condition
Can this hypothesis be eliminated?
The
following counterexample answers this in the negative. Example 1.
Let
A be a regular local ring of dimension 2, and
let
{s,t}
be a set of uniformizing parameters for the ring
Let
C*
A.
be the (non-negative) differential graded A-algebra
l such that C = A, C = free A-module of rank 1 with basis {x} , 2 3 C = free A-module of rank two with basis {h,k}, C = free
°
A-module of rank one with basis one with basis Make
C*
{u},
and
ci=O
{z} ,
c
4
= free A-module of rank
all integers
iI0,1,2,3,4.
into a
(non-negative) graded
O-algebra by requiring
1 E cO
be a two-sided multiplicative unit,
that
x
2
=h
2
=k
2
=z
2
= xh = hx -= xk = kx =
hz = zh = kz = zk = 0, xz=-zx=kh= hk=u. Then
C*
is a skew-commutative, non-negative graded A-algebra,
and we see that the graded A-algebra C* obeys Poincare duality. i i i+1 Define d :C + C , all integers i, to be the unique homomorphism of A-modules such that dO=d 3 =0, d
l
(x) =
st • h,
720
Chapter 7 d
2
(h) = 0,
2 d (k)=st
and
(Thus, necessarily or c*,
i
~
z.
o
d
i
= 0
for all integers
i
such that
i < 0
Then one readily verifies that the graded A-algebra
3).
just defined,
together with the coboundaries
is a non-negative, skew-commutative differential graded A-algebra. (The computation is similar to that in Example 3 following Theorem 2).
0 = A/tA
Let graded
k =AA t, s} • A.
and
Then
C* /tC*
is the
O-algebra: cO /tC O = 0,
l Cl/tC "" 0,
c 2 /tC 3
2
"" 0 Ell 0,
3
C /tC "" 0, 4 4 c /tC "" O.
and
The coboundaries in the d.g.a. (since i
~
2,3).
d
l
modulo
C*/tC*
t,
over
0
are zero, and
are all zero d
i
= 0,
Therefore
(1)
As graded O-algebra, Hi (C*/tC*),
iE~)
C*/tC*
(and therefore also
is isomorphic to the graded O-algebra con-
structed explicitly in Example 3 following Theorem 2. by Example 3 following Theorem 2, the graded O-algebra
Therefore, c*/tc*--
and by equation (1) therefore also the graded O-algebra Hi (C*/tC*), i E 2'-obeys Poincare duality, with the fourth the
Poincar~
highest non-vanishing group. orem 3 holds.
721
Duality
Thus, the hypothesis (5) of The-
The reader will immediately verify that the other
hypotheses of Theorem 3, except the hypothesis that injective as
AltA-module, all hold
AltA
(since all the groups in
question are finitely generated over a Noetherian ring
0».
is
(A
or
(Of course, hypothesis (1) must be replaced by hypothesis
(1") of Note 2 to Theorem 6, in the case that cally complete.
A
But the reader can insist that
complete - or even that
A
is not t-adiA
be t-adically
be a complete local ring, if desired-
and then hypothesis (1), and hypotheses (1') and (1") of Note 2 of Theorem 3 all hold). However, explicit computation shows that HO (C*) = A,
(2)
Hl (C*) = 0, 2
H- (C*) "" A/st • A,
H3 (C*) "" A/st • A, and
H4 (C*) "" A.
Therefore, ditions Chapter
H4 (C*)
is a free A-module of rank one, so that con-
(2), (2'), (3), (3') of Theorem 3 hold.
6, it follows that conditions (4) and (4') of Theorem
3 also hold, and therefore so also does (4") lent to (4». (3)
By Theorem 4 of
(which is equiva-
But from equation (2) we deduce that
HO (C*) I (topological t-torsion) = A, H1(C*)/{topological t-torsion) == 0, H2 (C*)/(topological t-torsion)
"".!!.. , sA
. ) A H3 (C*)/(topological t-tors~on "" sA '
and
H4 (C*) I (topological t-torsion) "" A.
722
Chapter 7
Thus, the (non-negative, skew commutative) differential graded A-algebra
Hi(C*)/(topological t-torsion),
obey Poincare duality over
A
iEZ,
does not
(in fact, the second and third
groups are not even reflexive; also the first group is zero, but the third isn't and the highest non-vanishing group is the fourth).
Therefore, condition (1) fails.
(Notice, amusingly
enough, that (I') of Remark 5 holds, and that all modules are finitely generated over
A).
we delete the hypothesis, even if
n = 4,
A
Hi (C*/tC*)
t
i
c =0
(and
"A/tA
is injective as
A/tA-module",
is Noetherian (even a complete local ring of
dimension two with negative,
Thus, Theorem 6 becomes false if
one of the parameters), for
i
~ 5),
are finitely generated
and
C*
is non-
i
C , Hi (C*) ,
A-,A-,
and
and
(A/tA)-modules,
respectively. It is of interest to see where the proof of Theorem 6 would break down in the above Example.
It is easy to verify in
the above example, that the differential graded algebra over (from the Bockstein spectral sequence of respect to the endomorphism "multiplication by in Chapter 1), is isomorphic, as d.g.a. over
t", 0,
C*
with
as defined
to the one
constructed explicitly in Example 3 following Theorem 2.
There-
fore, by Example 3 following Theorem 2, the cohomology of that d.g.a., which is over and
0,
i E , l
i EZ,
does not obey Poincare duality
and in fact explicitly
o
El = 0,
1 El = 0,
2~
El ~ jk,
3 El"" k
This is the point at which the proof of Theorem 6
would break down (precisely when one would have to use Theorem 2) •
It is also not difficult to see that in Example 1,
Poincare Duali ty all integers
723
(In fact, this is because in
i.
Hi(C*),
every
2 precise t -torsion element is a precise t-torsion element. Proposition 3 of Chapter 1 then implies the indicated result.) (Another computation of
can be obtained using the short
exact sequence (*) of Theorem 2 of Chapter 1 - the third group in
these sequences vanish, since
as A-module and
A
Hi(C*)
is finitely generated
is Noetherian, and therefore
Hi(C*)
has
no non-zero t-divisible elements.) Notice that Example 1 above has two other curious properties: Namely, the d.g.a. does the d.g.a.
C*
over
C*/tC*
A
over
obeys Poincare duality, as
A/tA=O.
The coboundaries in the d.g.a. i zero, so that Hi (C*/tC*) =c ,
A more novel detail:
C*/tC*
over
all integers
of course, the coboundaries
A/tA(=O) i.
are all
(Although,
in
are not zero, but are the ones constructed in Example 3 following Theorem 2.
x,h,k,s
1 -
(Thus,
dO (xl
= sh,
are the images of
x,h,k,s
we have that Remark 6'.
2 dO(k)=sz,
2 dOth) = 0,
for
in
C*/tC*.)
where
Again, since
j ~ 1.
Of course, it is easy to make trifling modifications
in Exmaple 1 above so as to obtain other counterexamples in which less coincidences occur. d.g.a. over
A
E.g., if
such that
A-module, all integers all integers
i,
duality over
A
duality over
A/tA,
i,
such that
Hi(D*)
D*
is any non-negative
is free of finite rank as
such that
Di
Hi (D*),
i E Z,
and such that
Hi (D*/tD*)
is flat as A-module, obeys Poincare obeys Poincare
C* 0 D*, where C* is as in A Example 1 above, is another counterexample to Theorem 6 with the hypothesis,
"A/tA
then d.g.a.
is injective as
A/tA-module" deleted.
E.g.,
724 let
Chapter 7 0* = the singular cochains of
the ring
A,
where
m
JPm«([;)
with coefficients in Then
is any positive integer.
C*
~
A
0*
is another counterexample to Theorem 3 with the hypothesis "AltA
is injective as
Remark 7.
AltA-module" deleted.
Suppose that all the hypotheses of Theorem 3 hold
except possibly for hypothesis (1)
(and also, that hypothesis
(I') and hypothesis (1") of Note 2 to Theorem 3 also need not hold).
Then, if in conditions (1), (2), (2'), (3), and (3') we re-
place each occurrence of the A-modules, t-torsion)",
"Hi(C*)/(toPological
"Hn(C*)/(topological t-torsion),"
and
"Hn(C*)1
t-divisible elements)", by their t-adic completions, i.e., by I\t the (A )-modules, (t-torsion) ]I\t"
and
i . I\t "[H (C*)/(t-torsl0n)] ," "Hn(C*)l\t"
n "[H (C*)I
respectively - and leave con-
ditions (4), (4') and (4") as is (and also in condition (1) write,
"graded A"t-algebra" and "Poincare duality over
Al\t"
in lieu of "graded A-algebra" and Poincar€! duality over
A"),
then the resulting Theorem is a true statement,
(one that does
not require any of the hypotheses (1), (I') or (I")).
The proof
is very simple. Proof:
Since
C*
obeys the hypotheses of Theorem 2 except
hypothesis (1) we see that the cochain complex of (C*)l\t
obeys all the hypotheses of Theorem 1.
Hons (1), (2), complex of and
C*
Therefore condi-
( 2 ' ) , (3) , (3' ) , (4) , (4 ') and (4"), for the cochain
Al\t-modules (C*)l\t
are all equivalent.
But
(C*)l\t
have the same generalized Bockstein spectral sequence
(since they have the same (C*)l\t
Al\t-modules
so that
(4) , (4') and (4") for
are,respectively,the same as (4), (4'), and (4") for
The short exact sequence (1.8) of [P.P.WCJ
C*.
(i.e., conclusion
725
Poincare Duality (1) of Theorem 1 of Chapter
2), applied to
C*, tells us that
the natural map is a monomorphism: (1)
Hi (C*)/\t ... lim Hi (C*/tjc*) ~
j~O
and similarly for
(C*)/\t,
,
so that we have the increasing
sequence of submodules: (2)
Hi (C*)/\tf.+H i ((c*)/\t)/\t~lj,m Hi (C*/tjc*). j~O
But the exact sequence (I.8) of [p.P.WCJ Theorem 1 of Chapter
2), applied to
(i.e., conclusion (1) of C*,
and hypothesis (2)
of Theorem 3 above imply that the monomorphism (1) is an isomorphism.
Therefore, so are both monomorphisms in the sequence (2),
i.e., the natural map is an isomorphism:
But, by Theorem 1 of Chapter 4 of
A/\t-modules
(c*)/\t,
applied to the cochain complex
we have that the natural map is an iso-
morphism:
all integers
i.
Equations (3) and (4) imply that we have a
natural isomorphism of (5)
A/\t-modules
Hi (c*)/\t"" Hi ((c*)/\t))/ (t-divisible elements),
all integers
i.
The isomorphisms (5) imply that each of the
A/\t-modules: Hi«C*)/\t)/(topological t-torsion),
726
Chapter 7
each integer
i,
Hn«c*)At)/(topological t-torsion) and Hn«C*)At)/(t-divisible elements) are respectively isomorphic to [Hi(C*)/(t-torsion)]At, [Hn(C*}/(t-torsion) ]At and
Hn(C*}At
respectively.
Substituting the latter three expressions into
conditions (1), (2), (2'), (3) and (3') for the former three expressions whenever they occur, the new conditions become the modified forms of the (five) conditions (1), (2), (2'), (3), (3') described in this Remark. the cochain complex of
This observation, and Theorem 3 for
(~t)-modules
(C*)At,
and our previous
observation that conditions (4), (4'), and (4") for the AAt-module (C*)At
are identical to the corresponding conditions for the
cochain complex of A-modules
C*,
completes the proof of Remark
7 •
Corollary 3.1:
Let
0
be a discrete valuation ring and let
be an element of the maximal ideal of
O.
Let
C*
be a differ-
ential graded O-algebra such that Either (1')
0
is a complete discrete valuation ring, and
Hi(C*)/(topolOgical t-torsion) O-module, all integers or
(1")
is a complete
i.
Hi(C*)/(tOPOlogical t-torsion) is finitely generated as O-module, all integers
t~O
i.
727
Poincare Duality Assume also that (2)
Hi(C*)
has no non-zero t-divisible, t-torsion elements,
all integers (3)
Multiplication by gers
(4)
i. i i t: C ... C
is injective, all inte-
i.
The graded
(O/tO)-algebra
Hi (C*/tC*),
iEZ,
is
non-negative, skew-commutative and obeys Poincare duality for some integer Then
Hi (C*/tC*)
all integers free
i,
and
n.
is finitely generated as
(O/tO)-module,
[Hi(C*)/(topological t-torsion)] is a
a-module of finite rank , all integers
i.
Also the following several conditions are equivalent:
(1)
The graded a-algebra i Ez ,
(1') Let
Hi(C*)/(topological t-torsion),
obeys Poincare duality for the same integer K
be the quotient field of
K-algebra
O.
Then the graded
[Hi(C*)/(tOPOlogical t-torsion)] @K,
a
iEz,
obeys Poincare duality. (2)
(Repeat condition (2) of Theorem 3, replacing by
(2')
(3)
(3')
(4)
(4')
"An
"0".)
(Repeat condition (4) of Theorem 3, replacing by
"A"
"0".)
(Repeat condition (3') of Theorem 3, replacing by
"A"
"0".)
(Repeat condition (3) of Theorem 3, replacing by
"A"
"0".)
(Repeat condition (2') of Theorem 3, replacing by
n.
"An
"0".)
(Repeat condition (4') of Theorem 3, replacing
"A"
728
Chapter 7 by
"0".)
(Repeat condition (4") of Theorem 3, replacing
(4")
"A"
"0".)
by
Also, when these equivalent conditions hold, we have that Hi (C*/tC*) i,
is finitely generated as
(O/tO)-module, all integers
and also that Hi(C*)/(topological t-torsion)
is a free O-module of finite rank, all integers
i.
And, when these equivalent conditions hold, we have also that every topological t-torsion element in
Hn(C*)
is t-divis-
ible. Note:
Hypothesis (3) above can be dropped, if in hypothesis (4)
we replace
"Hi(C*/tC*)"
changes in conditions (4), Proof:
H~(C*,O/tO)'"
by
and make similar
(4'), and (4").
Hypothesis (1')
(respectively:
(1"»
of the Corollary
implies hypothesis (1')
(respectively:
(1"»
of Note 2 to Theo-
rem 3.
Hypotheses (2), (3) and (4) of the Corollary imply, re-
spectively, hypothesis (2), (3) and (5) of the Theorem. thesis (4) of Theorem 3 is true (since (O/tO)-module, whenever tEO,
t"F 0,
3 holds.
0
And hypothesis (6) of Theorem
By hypothesis (4) of the Corollary and conclu-
sion (1), Proposition 1, we know that (O/tO)-module.
Therefore
(O/tO)-module.
Since
module of module.
is injective as
is a discrete valuation ring and
as is easy to see).
(Proof:
O/tO
Hypo-
Hi (C*/tC*)
Hi (C*/tC*)
(O/tO)
Hi (C*/tC*)
is a reflexive
is finitely generated as
is a Noetherian ring, every sub-
is also finitely generated as (O/tO)-
This proves hypothesis (6) of Theorem 3).
Therefore
729
Poincare Duality
the hypotheses of Theorem 3 hold, and therefore we have that conditions (1), (2), (2'), (3), (3'), (4), (4')
and (4") are equiva-
lent. Also, we have observed that
Hi(C*/tC*)
is finitely gener-
ated as (O/tO)-module (whether or not conditions (1), ••• ,(4") hold).
Therefore, since
quotient
of
logical t-torsion).
O/tO
is Noetherian, so is the sub-
Hi (C* /tC*) .
i
Let
i
D = H (C*)/(topo-
Then by the proof of Theorem 3, we have
that (1)
Also, by either hypothesis (1') or hypothesis (1"), Di,
finite subset of the image of
S
(O/tO)-module.
then
generates
Di
S
is a
as O-module iff
i (O/tO) generates D @ (O/tO) as 0 0 (The proof of this assertion was given in the in
i D
S
if
@
proof of conclusion (4) of Proposition 2 of Chapter
6).
But
we have just seen that
is finitely generated as (O/tO)-
module.
(1), Di is finitely generated as
Hence by equation
O-module.
Since
Di
has no non-zero t-torsion, and
discrete valuation ring, it follows that
Di
0
is a
is free of finite
rank as O-module. Finally, the equivalence of conditions (1) and (I') follows from Remark 5 above, and the fact, observed just above, that condition (1) imples that
Hi(C*) / (topological t-torsion) is
finitely generated as O-module. follows: group
Obviously
(l)~(l').
(The argument proceeds as By Theorem 4 of Chapter
6, the
M=Hn(C*)/(t-divisible elements) is simply generated as
A-module, and condition (2) holds iff the annihilator ideal of
Chapter 7
730
M is
{O}.
But, if condition (I') holds, then
[Hn(C*)/(topological t-torsion)] is a free A-module of rank one, and therefore its annihilator ideal, and a fortiori that of
M,
are zero.
tion (I') implies condition (2). equivalent to (I'».
Thus
Therefore condi-
(l)~(l')~(2),
(1)
is
This proves the Corollary.
The proof of the Corollary in the situation of the Note to the Corollary is similar. Example 1.
Let
p
Q.E.D.
be any rational prime and let
ring of p-adic integers,
and let
t = p.
calization of the ring of integers ated by
p.
Let
X
1L
Let
1L (p)
A =1L, p
the
be the lo-
at the prime ideal gener-
be any topological space.
Then we claim
that the following several conditions are equivalent (where the homology and cOhomology groups are all the usual singular homology and cohomology). (1)
Hi (X,1L/p1L)
is finitely generated, all integers
i,
(I' ) Hi (X,1L/P1L) is finitely generated, all integers i, i (2) H (X,1L ) is finitely generated over 1Lp' all intep A
i,
gers A
(2' ) H. (X,1L ) 1
gers (3)
P
is finitely generated over
Hi(X,~)
and «3) (b»
«3) (b»
The p-torsion in integers
below hold:
is a finite dimensional rational vector
space, all integers and
all inte-
i,
Both conditions «3) (a»
«3) (a»
1Lp'
i.
i,
Hi (X,1L)
is a finite group, all
Poincare Duality (3')
731
Both conditions « 3' ) (a)) and «(3') (b) ) «3') (a))
Hi (X,(I)
is a finite dimensional rational
vector space, all integers «3') (b))
The p-torsion in
i
H (X,Z (p))
(4')
Hi(X,z (p))
is finitely generated as
p}
Js
1
p}
EZ
such that
s
is prime
i.
(l)~
(1'),
group in (1) is the
«3)
(2)-=;' (2'),
«3)(b))~«(3')(b)),
and
(4)~(4')
(Z/~)-dual
(a))~
( (3') (a)),
(5)~(5').
of that in (I').
in (2') is the direct sum of the
zp)'
is prime
The usual universal coefficients theorem of topology
shows that
A
s
is a finitely generated abelian group, all
integers
Exti
such that
i.
H. (X,Z ) / { x : s· x = 0,
to
Proof:
]sEZ
is a finitely generated abelian group, all
integers (5' )
z(p)-module,
i.
i H (X,Z)/{x: s· x=O,
to
Z (p)-module,
i.
all integers (5)
is a finite
i.
is finitely generated as
all integers
i.
Hi (X,z)
group, all integers (4)
below hold:
2 p -dual
(In fact the And the group
of that in (2) and
(the group in (2) with a dimension shift of minus one), p
from which the equivalence of (2) and (2') follows.
(3) (a))-=- ((3') (a)), ... ,
(4)~ (4')
are proved similarly). Also,
by the usual universal coefficients theorem for homology,
i.. p
H. (X,Z )""'H. (X,Z( )) (S9 1 P 1 P Z
Since
~p
is faithfully flat as
(p)
z(p)-module, conditions (4') and (2') are equivalent.
From the
homology (or cohomology) sequence of the short exact sequence:
o .... zp
~zp .... (Z/pZ) .... 0,
we see immediately that (2') implies
732
Chapter 7
(1')
(or that (2) implies (1».
Thus, to establish the equiva-
lence of (1), (1' ) , (2) , (2' ) , (4) and (4') it is necessary and sufficient to prove that
(1)~(2).
We use Theorem 1 of Chapter 5. chains of Hi(C*)
X
with coefficients in
=Hi(X,~) p
and
Let A =?L
C* = the singular coand let
p
Hi(C*/tC*)R>Hi(X,Z/p;l),
t = p.
Then
all integers
i.
Therefore if condition (2) holds then all the hypotheses of Theorem 1 of Chapter 5 hold, and therefore the conclusion, that is condition (1), holds. We leave it to the reader to struggle out, using universal coefficients, that
(4')~(5').
(4'), and the fact that HOnz (Hi (X,Z) ,Z (p»
obviously
(5')~(3'),
One uses both condition
H.(X,;l)GZ( )R>H.(X,Z( Z
l
e ExtZ (H i - l
HOnz (p) (Hi (X,Z (p»'z (p»
(Hint:
pl. l
P
»,
(X,Z) ,Z (p) ) R> H (X,;l (p) )
i R> H (X,Z (p) ),
all integers
and that i).
Since
and fairly easily (using the homology se~
quence of the short exact sequence:
o .. Z
universal coefficients observation:
Hi (X,;l)
z .... Z/p:l ~~
.... 0,
'" Hi (X,[) ,
and the all
Z
integers
i),
(3')~(l'),
it follows that (3') and (5') are
also equivalent to each of the conditions (1), (I'), (2), (2'), (4),
(4').
Q.E.D.
Remark:
The use of Theorem 1 of Chapter 5 in the above example
can be avoided because of the simplicity of the ring a complete discrete valuation ring). A
However,
is a regular local ring of dimension 2 and
A
(namely,
even if,e.g., t
is part of a
set of uniformizing parameters, then Theorem 1 of Chapter 5 is not obvious.
Such applications,
(for very general
A), occur in
[P.AS::J.
The following amusing example from topology is of course
Poincare Duality
733
very familiar. Example 2.
Let
"'z
A
the localization of the ring of in-
(2)'
tegers at the prime ideal generated by 2, a discrete valuation ring.
Let
t'" 2 \; A.
fold and let in
A.
Let
be any connected topological mani-
C* = the singular cochains of
X
with coefficients
Then it is well known that all the hypotheses of Corol(The outstanding observation being hypotheses
lary 3.1 hold.
(4), that the graded i ( = H (X, (Z/2Z)),
n
X
= dimension
proof) .
X,
z/2z-algebra
i E Z)
Hi (C*/tC*),
i E z,
obeys Poincare duality for the integer
which is proved by the familiar topological
(The other hypotheses of Corollary 3.1 are satisfied,
since by Example 1 above (just the equivalence of (1), (I'), (2), ( 4 ) and ( 4 I as
)
)
we know that
Z (2) - module, all integers
Hi(X,z/~)
i
is finitely generated
H (X'Z(2» i
(condition (4»
is finitely generated, all integers
(1», and this latter holds since the graded i H (X,z/2z), i H (X,Z/2Z)
i\;Z,
since i
(condition
(z/2Z)-algebra
obeys Poincare duality, and therefore
is a reflexive (Z/2Z)-module, and therefore finitely
generated).
Therefore, by Corollary 3.1, the following condi-
tions are equivalent (noting that, by definition of singular cohomology, (1)
Hi (C*) = Hi (X,Z (2) ), the usual singular cohomology):
The graded Z(2)-al g ebra
i H (X'Z(2»/(2-torsiOn),
obeys Poincare duality for the integer (I' )
The graded rational algebra
H
i
(X,[),
iE;z>:,
n. i E;z>:,
obeys
poincare duality. (2)
n H (X,;z>: (2»
(4)
n l ~ d - : En-l~En r r r
is a free Z (2)-module of rank one. . th e zero map, a 11 1n . t egers 1S
r> O.
734
Chapter 7 (4' )
E~
(4")
is of dimension one as Cz/ZZ)-vector space.
Of course, the equivalence of these conditions is essentially well known, and the topological
~anifold
X
is called orientable
iff each of these equivalent conditions hold. Notice that by Theorem 4 of Chapter 6,
Hn(X,~)
is a cyclic group.
we have that
Therefore another condition equiva-
lent to (1), (2), (4), (4') and (4") is
(2.0)
The annihilator ideal of
Hn(X,Z (2))
is zero.
It is well known that, when the above equivalent conditions
X
fail, i.e., when
is not orientable, that in fact
Hence, using the results of Chapter 1, in this case (4.1)
n-l dO
is surjective,
dn-l=O, r
all integers
r > 1.
and ( 4. 1 ") E~ = 0 •
Conditions (2.1),
(4.1) and (4.1") are therefore equivalent, in
this case, to the negation of each of conditions (1), (1'), (2), (4),
(4') and (4").
the condition:
(Condition (4.1) is therefore equivalent to
IId~-l 'I 0").
Of course, all of this is well-known by other, more topological methods.
(Except for the equivalence of condition (1) with
the other conditions, as (I') is the condition usually stated). Of course, there are other, less well kno\'ln,
(and less
trivial) applications of Corollary 3.1 and of Theorem 3, in parti-
Poincar~
cular to algebraic geometry.
Duality
735
(E.g., see the examples earlier
in this chapter after the statement of Axioms (P.0l) and (P.U2)).
This Page Intentionally Left Blank
CHAPTER 8 FINITE GENERATION OF THE COHOMOLOGY OF COCHAIN COMPLEXES OF I-ADICALLY COMPLETE LEFT A-MODULES FOR A FINITELY GENERATED IDEAL I
Throughout most of this manuscript, we have dealt with a simply generated ideal,
t-A.
Certain results can be general-
ized to finitely generated ideals.
Some such theorems, analo-
gous to those in Chapter 4 , will appear in a later paper.
But
we generalize most of the theorems of Chapter 5, including Theorems 1 and 5, here. Definition 1.
Let
First, we pose some definitions. A
sequence (t , ... ,t ) l r ring
A
be a ring with identity. of elements of
if it is of length
r,
A
Then a finite
is an r-sequence for the
and if the following two condi-
tions hold. (1)
The right ideal generated by
sided ideal,
tl, ... ,t i
is a two-
1 < i < r.
(It is equivalent to say that
Ati c tlA + '"
+ tiA,
1 2. i 2. r), and (2)
If
ti
is the image of
AI (tlA + •.. + ti_1A) , then the function, "left multiplication by
is one-to-one,
t i "..
1 < i < r. 737
ti
in the quotient ring
738
Chapter 8
Definition 2.
Let
left A-module. of
A
be a ring with identity and let
Then a finite sequence
(tl, .•. ,t r )
A is an r-sequence for the left A-module
length
r,
(1) A-module
M
M
be a
of elements
if it is of
and if the following two conditions hold: tIM + ••• + tiM,
The abelian subgroup, M
is a left A-submodule,
(It is equivalent to say that
of the left
1 < i < r. AtiMc tIM + .. , + tiM,
i .::. i.::. r), and (2)
For each integer
morphism, "multiplication by M/tlM + ... + ti_lM, Clearly, if tive integer and A,
A
A
(tl, .•. ,t r )
~O,
ring for
A, A"
and
r
a non-nega-
a finite sequence of elements of
is an r-sequence for the ring (tl, ... ,t ) r
A
in the
is an r-sequence for the
in the sense of Definition 2.
Also clearly, if ger
M - = i l
of the left A-module
t.1. "
is any ring with identity,
sense of Definition 1 iff left A-module
we have that the endo-
is injective.
(tl, ... ,t r )
then
1 .s.. i .s.. r,
i,
A
(tl, ... ,t ) r
is a ring with identity, a sequence of
r
r
an inte-
elements of the
then if condition (1) in the definition of "r-sequence holds, then for every left A-module
in the definition of
M,
condition (1)
"r-sequence for the left A-module
M"
holds. If A,
A
is any ring with identity and
then let
(S)
tity
A,
any sequence of and if
is any subset of
denote the two-sided ideal generated by
Then it is easy to see that, if tl, ... ,t r
S
M
r
r
is any integer
~
S.
0,
elements of the ring with iden-
is any left A-module such that condition (1)
in the definition of "r-sequence for the left A-module
M"
Finitely Generated Ideal
739
I
(that is, condition (1) of Definition 2) holds, then the left Mi = M/ (tlM + ... + tiM)
A-module
quotient ring Example 1.
is a left module over the
A/({tl, ... ,t i }).
In the case that the ring
A
is commutative, Defi-
nitions 1 and 2 agree with the familiar ones posed by AuslanderBuchsbaum ([A.B.)). Example 2. Then
A
Let
be a Noetherian, commutative local ring.
is regular iff there exists an n-sequence
for the ring that
A
In particular,
A
tl,···,t n
Example 3.
Let
where
n
(tl, ... ,t ) n is the Krull dimension of A, such
generate the maximal ideal of A
be a ring with identity and let
be a finite sequence of elements of left A,
A-module.
A.
If
(tl, ... ,t r )
A.
Let
(tl, ... ,t r )
M be any flat
is an r-sequence for the ring
then
(tl, .•. ,t r ) is likewise an r-sequence for the flat left A-module M. (This Example is a special case of Lemma 2
below. ) We are now ready to state and prove a generalization of Theorem 1 of Chapter 5. (This generalization is not as strong as Corollary 1.1 below. ) Theorem 1.
Let
left ideal in
A
A
be a ring with identity and let
such that
A
that there exists an integer such that
tl, ... ,t r
we have a
(~-indexed)
generate
I
be a
is I-adically complete.
r,
and elements I
t l , ... , tr E I
as left ideal.
cacha in complex
C*
Suppose
Suppose that
of left A-modules,
such that (1)
ci
is I-adically complete for all integers
i.
Sup-
Chapter 8
740
pose also that the ring
(2)
A
is left Noetherian (*), and that i (tl, ... ,t ) is an r-sequence for c , iE7, r
The sequence
(E.g., this is the case if (tl, ••• ,t r ) is an r-sequence for the ring A, and if c i is a flat A-module, all integers i.) Suppose also that
i C
module integers Let
n
+ t ,C i
The left submodule
(2' )
of the left A-
J
1::, j
is closed for the I-adic topology,
::. r-l,
all
i.
be a fixed integer. n H «A/I)0 C*)
(3)
Then if
is finitely generated as left A-module,
A
for the fixed integer
(4) Proof:
HnCC*) For
n,
then
is finitely generated as left A-module.
r = 1,
this is Theorem 1 of Chapter 5.
Theorem is true for
r-l;
to prove it for
the two-sided ideal in the ring
A
r.
Suppose the
Let
generated by
I r l
be
tl, ••. ,t _ • r l
Then by condition (1) of Definition 2, the left A-module i i i C /(tlC + ••. + tr_lC) each integer
i.
is also a left
(A/lr_l)-module, for
But then the hypotheses of Theorem 1 of Chap-
ter 5 apply, to the ring and the cochain complex
A' = A/I
r-l'
the element
t
= tr E A',
«A/lr_l)QC*) (=C*/(tlC*+ ••• +tr_lC*).) A
Therefore, by Theorem 1 of Chapter 5, we have that
is finitely generated as left (A/lr_l)-module.
But then, apply-
ing the inductive assumption to the cochain complex ring
A,
the ideal
I - , r l
and the sequence
C*,
the
(tl, ••. ,t _ ), it r l
follows that
e*) erated.
In the sense that every left ideal in A is finitely gen-
Finitely Generated Ideal
741
I
is finitely generated as left A-module. Remark:
Theorem 1 as stated is perhaps too restrictive in its
hypotheses.
In particular, the topological hypothesis (2')
would be a bit annoying in applications.
We shall see (e.g.,
in Corollary 1.1, following Lemma 3) that Theorem 1 can be improved as follows: 1.
If, in Theorem 1, we delete the technical hypothesis
(2'), but insert instead the technical condition (TC) of Lemma (tl, ••• ,t ) is an r-sequence r then the Theorem remains valid.
1.1.1, and assume also that in the ring 2.
A,
If, in Theorem 1, we delete the technical hypothesis
(2'), and instead assume that the elements the center of the ring
A,
Proof of assertion 1:
If
the ring
A,
tl, ... ,t
n
are in
then again Theorem 1 remains valid. is an r-sequence for
then since we have hypothesis
(2) of Theorem 1,
it follows from Corollary 2.1 that the natural map is an isomorphism:
Therefore Corollary 1.1 completes the proof of assertion 1. Proof of assertion 2:
The notations being as in Corollary 1.2,
is an r-sequence in the ring then by hypothesis (2) of Theorem 1 (Tl, ... ,T ) r m for the Z(Tl, ... ,Tr)-module C , all integers
Z(T , ... ,T ), r l is an r-sequence m.
Therefore
by Corollary 2.1 the natural map is an isomorphism of left Amodules:
742
Chapter 8 Hn'T T) (Z\Tl,···,T )/(Tl,···,T ),C*} "'iZ ' l ' ... ' r r r
Therefore Corollary 1.2 implies assertion 2. Corollaries 1.3 and 1.3' below are additional refinements of Theorem 1,
(which do not involve "percohomology groups", but
involve higher Tor's, with coefficients in
A/ (tlA + ... + trA)
in Corollary 1.3', and with coefficients, over in
Z\T , ... ,Tr)/(T , ..• ,T } r l l
in Corollary 1.3}, in the case
is not an r-sequence for
that m
Z(T , ... ,T ), r l
all integers
(and, in fact, when both conditions (2) and (2') are removed).
{In Corollary 1.3, one assumes that the elements the ring
A
tl, .•. ,t
r
of
are in the center of the ring; in Corollary 1.3',
one assumes instead that the technical condition {TC} of Lemma 1.1.1 holds, and that ring
(tl, ••• ,t ) r
is an r-sequence in the
A.} Corollaries 1.1 and 1.2 {following Lemma 3} are other gen-
eralizations of Theorem 1.
Both involve percohomology groups
(in Corollary 1.1, the group lary 1.2, the group
H~(T I.l..
H~(A/(tlA+ •.• +trA),C*}; in Corol-
1'···'
T) (Z(Tl, .•. ,T )/(Tl, ... ,T ),C*}, r
and very mild hypotheses on the ring (TC) of Lemma 1.1.1 holds, ~ that center of the ring
A.}
r
A
r
that either condition
tl, ••• ,t
are in the r (And, in all of the Corollaries 1.1,
1.2, 1.3 and 1.3', neither hypothesis (2) nor hypothesis (2') of Theorem 1 is required, vide infra.) Lemma 2. ~o,
Then
Let
and let
A
be a ring with identity, let
(tl, ... ,t r )
r
be an integer
be an r-sequence for the ring
A.
Finitely Generated Ideal 1.
If
M
is any left A-module, we have that
all integers 2.
If
conditions, (2a)
M
743
I
i,j,
with
02.i2.r,
j.:.i+l.
is any left A-module, then the following three
(2a),
(2b) and (2c), are equivalent:
(t , ... , t ) l r
is an r-sequence for the left A-module
M; (2b)
+tiA),M) =0, all integers
i,
(2c)
all integers
j':'l,
12. i 2. r; +tiA»,M) =0,
all integers
i,
l
The proof is by induction on
tion is trivial.
Suppose that
known for the integer
r-l.
r >1
r.
For
r = 0,
the asser-
and that the Lemma is
Then since
(tl, ... ,t _ ) r l
is an
(r-l)-sequence, by the inductive assumption we have conclusion 1 of the Lemma for
02.i2.r-l,
j.:.i+l,
and also the equiva-
lence of (2a), (2b) and (2c) for the integer
r-l.
conditions
", respectively.)
Since
"(2a)r_l"' "(2b) (tl, ..• ,t ) r
r-l
"and "(2c)
r-l
(Call those
is an r-sequence in the ring
A,
have the short exact sequence of (right) A-modules:
o -+-
(left Iilul tiplica tion by [Aj (tlA + ... + tr_lA) 1 [Aj (tlA + '"
+
tr_1~1 -+-
trJ
--------------------------~~.>
[Aj (t A + ... + trA) 1 l
which yields the long exact sequence of Tor's:
(1) + tr_lA»
,M)->
-+-
0,
we
Chapter 8
744
By conclusion 1 of the Lemma for the integer A
Tor j ((AI (tlA + ... + tr_lA»
,M)
=
0
for
j
~r.
r-l, we know that Therefore from
the long exact sequence (1), we deduce that A
Tor.((A/(tlA+ ... +t A»,M) =0
j~r+l.
for
r
J
This completes the inductive verification of conclusion 1. Next, let us prove the equivalence of (2a), (2b) and (2c). By the inductive assumption, we can assume that (2b)r_l
both hold--i.e., that
sequence for
M,
(t , ... ,t _ ) r l l
(2a)r_1 and is an (r-l)-
and that
A
Tor.((A/(tIA+ ... +t.A»,M) =0, J
1
j~l,
all integers
i,j
with
l
We must show that (3)
(left multiplication by
t ): r
MI (tl M + ... + tr_IM) ...
MI (tIM + ... + tr_lM) is injective if and only if (4)
all integers
and that condition (4) for the integer all integers
j
~
1.
equation (2b) r-l' for
j
~
2,
j = I
j
~l;
implies (4) for
But from the long exact sequence (1) and we see that
and that
A
Tor j ( (AI (tlA + ... + trA) ) ,M) = 0
A
TorI ((AI (tlA + .•• + trA»
only if condition (3) holds.
,M) = 0
i f and
This completes the inductive proof
of the equivalence of (2a), (2b) and (2c). Corollary 2.1.
Let
A
be a ring with identity, let
r
be an
Finitely Generated Ideal ~O,
integer ring
A.
Let
and let C*
(tl, ... ,t r )
745
I
be an r-sequence for the
be a (z-indexed) cochain complex of left A-
modules. If (tl, ... ,t ) is an r-sequence for the left A-module r m c , all integers m, then the natural map is an isomorphism of A-modules
all integers Proof:
i.
Ey hypothesis,
m C
obeys condition (2a) of Lemma 2, and
therefore obeys condition (2b) of Lemma 2, for all integers 1,:, i .:. r,
and in particular for
i = r,
all integers
m.
i,
The
Corollary then follows from the definition of percohomology (Chapter 5, Lemma 2.1.1). Lemma 3. ¢:B ->-A
Let
and
B
be rings with identity and let
be a homomorphism of rings with identity.
integer ring
A
B,
~O,
and let
(ul' ... ,u r )
Let
r
be an
be an r-sequence in the
such that, if
ti = ¢ (u ), i is an r-sequence in the ring A. Let
C*
be any cochain com-
plex, indexed by all the integers, of left A-modules. Then if i we regard C as a left B-module by means of the homomorphism of rings,
¢:B->-A,
all integers
i,
then the natural mappings
are isomorphisms:
all integers
n E;z.
(where the cohomology groups are the per-
cohomology groups as defined in Chapter 5). Proof: The proof is by induction on the integer r
=
0
the assertion is trivial.
Suppose
r >1
r >
o.
For
and that the
746
Chapter 8
assertion is established for the integer (u ' ... ,u - ) r l l
and
rings
A
B
and
(tl, ... ,t r _ ) l
r-l.
Then
are (r-l)-sequences in the
respectively, so that by the inductive assump-
tion we have an isomorphism analogous to the conclusion (1) of the Lemma with r-l replacing
r.
From the short exact sequence:
(left multiplication by
and the analogous short exact sequence with "B"
"t.
and
replacing
II
~
"U
i
",
"A"
u ) r >
replacing
we have the long exact se-
quences of percohomology: n-l
(2)
~ HB((B/(UIB+ n
H~((B/(uIB+
+ ur_lB))
,C*)~
d
n
+ UrB)) ,C*)....:;:........ ••• and n-l (3)
d
t
'>
H~((A/(tlA+ ... +tr_lA)),C*)--'£"'" H~((A/(tlA+ ... +tr_lA)),C*)
H~( (A/(tlA + ... + trA)) ,C*) d The ring homomorphism into the sequence (3).
----;>
n
>
induces a mapping from the sequence (2)
cP
The inductive assumption and the Five
Lemma complete the proof. Remarks:
1.
Of course, if we delete either the hypothesis that
"(ul' ... ,u ) is an r-sequence in r an r-sequence in
A",
very easy to construct.
B",
or that
then Lemma 3 fails.
"(tl, ... ,t r )
is
Counterexamples are
Finitely Generated Ideal
747
I
Before stating and proving Corollary 1.1 below, we require a Lenuna. Lenuna 1.1.1. teger A.
>0
Let
Let
A
and let I
tl, ••• ,t r • (TC)
be a ring with identity. Let (t , ••• , t ) r l
be an in-
be an r-sequence for the ring
be the right (= two-sided) ideal generated by Suppose that
A
is I-adically complete, and that
For every free left A-module
we have that the are closed in
~I
i < i < r - 1.
for the I-adic topology,
Then for every free left A-module is an r-sequence for
F,
AI AI tl F + ••• + ti F
left A-submodules:
Note.
r
F,
we have that
(tl, ••• ,t ) r
FAI.
The technical condition (TC) is equivalent to the condi-
tion that (TC')
The I-adic topology on the ideal
ti(A/(tlA+ ••• +ti_1A»
AI (tlA + ••• + ti_1A)
A _l i
tuple: tuple:
A _ , i l
is I-adically Hausdorff.
(Xj)jES (tixj}jES
1 < i < r - 1.
By induction on
(TC ' ) for the integer
i
in
If
i, S
we can assume that is any infinite set, then
is equivalent to asserting that, a
A~_l
in
Ai _ l =
is the induced topology from the
I-adic topology of Proof of the Note.
in the ring
S
Ai _ l
converges I-adically to zero iff the converges I-adically to zero.
this latter is equivalent to asserting that I-adically closed in
(Al~i)AI; i.e.,
(tlA + ••• + tiA) «A (S) )1\1) Proof of Lemma 1.1.1.
t. ({A~S»AI) ~
~-l
And is
that
is I-adically closed in
The proof is by induction on
(A (S) )1\1. r.
748
Chapter 8
By (TC),
tl«A(S))AI)
is I-adically closed in
(A(S))AI.
Hence
(A(S))AI/tl«A(S))AI) is I-adically Hausdorff, and is therefore isomorphic to «A/tlA) (S))AI
But then the ring
the (r-l) -sequence (t 2 + tl A, ••• tr + tl A),
A/tlA,
and
obey the hypotheses
of the Lemma.
Q.E.D.
A more general, and possibly more elegant, statement than Theorem 1 is the following Corollary,
(which makes use of per-
cohomology as defined in the latter part of Chapter 5). Corollary 1.1.
Let
A
be a ring with identity, let (tl, ... ,t ) r
non-negative integer and let the ring let
A.
Suppose that the ring
1= tl A + ..• + trA
A
r
be a
be an r-sequence in
is left Noetherian, and
be the ideal generated by
{t ,·,·, t } . r l
(By the Remark following Definition 1, the right ideal and the two-sided ideal generated by Suppose that the ring
{tl, ... ,t } r A
coincide.)
is I-adically complete, and that
the technical condition (TC) of Lemma 1.1.1 holds. to Lemma 1.1.1,
(TC) of Lemma 1.1.1 is equivalent to (TC ' ) of
the Note to Lemma 1.1.1). eliminated if the elements ring
Ai
(By the Note
(The technical condition (TC) can be tl, ••• ,t
r
are in the center of the
see part (2) of the Remark following Proposition 4.)
(Also, if the ring
A
course holds, since
A
is commutative, then condition (TC) of is by hypothesis Noetherian.
the Krull intersection theorem to prove
(TC ' )
(One uses
of the Note to
Lemma 1.1.1)). Let such that n
C* C
be a i
(Z-indexed) cochain complex of left A-modules
is I-adically complete for all integers
be a fixed integer. (1)
H~(A/I,C*)
i.
Let
Then if the percohomology group is finitely generated as left (A/I)-module,
Finitely Generated Ideal for the fixed integer (2)
Hn(C*)
fixed integer proof:
n.
Choose a
Cl'-indexed) cochain complex
i H (¢*)
and such that
'C*
of left
¢ *: 'C* ->- C* of cochain complexes of left i 'C is free as left A-module, all integers
A-modules such that
i H (¢*)
Then since
then
is finitely generated as left A-module for the
A-modules and a map
i,
n,
749
I
is an isomorphism, all integers
is an isomorphism, all integers
i,
i.
from
the universal coefficients spectral sequence:
and the similar spectral sequence for (1)
H!(A/I,¢*)
ci
Since image of
¢*
(~-indexed)
(2)
Since
'C
it follows that
is an isomorphism for all integers
i.
is I-adically complete for all integers under the functor
i,
the
"I-adic completion" is a map of
cochain complexes of left A-modules
(¢*)I\:
i
'C*,
('c*)1\
-+C*,
where
"1\"
= "1\1".
is free as left A-module, all integers
i,
and
since we have the condition (TC) of Lemma 1.1.1, by the conclusions of Lemma 1.1.1, we have that the left A-module is such that
(tl, ... ,t r )
(ICi)1\
is an r-sequence, all integers
i.
Therefore by Corollary 2.1 we have that H! (A/I, 'C*) "" Hi ((A/I)
@
'C*),
A
H! (A/I,
('C*)I\) ""
H! ((A/I)
@ ('C*)I\),
all integers
A
Since also
(A/I)
@
A (3)
[(,c*)I\]
""(A/I)
@
('C*),
it follows that
A
H!(A/I,'C*)""H!(A/I,('C*)I\),
all integers
i.
i.
Chapter 8
750
Combining equations (1) and (3), we see that the map (4)
Hi (A/I, (¢*)"): Hi (A/I, ('C*)") ... Hi (A/I,C*)
is an isomorphism, all integers
ci
i.
i (IC )"
But since
and
are I-adically complete, it follows from Proposition 4
Hi(~*")
below, and equation (4), that
is an isomorphism of
left A-modules,
all integers
i.
Therefore to prove the conclusion, equation
(2), of the Corollary it suffices to prove the corresponding assertion for the cochain complex conclusions of Lemma 1.1.1,
i
( I C )" , i
tl('C )"+ ... +tj(IC )" integers
i.
(tl, ••• ,t ) r
i
for the left A-module
('C*)".
of
But by (TC) and the
is an r-sequence
and the submodule i (IC )"
is closed,
l~j~r-l,
Therefore the hypotheses of Theorem 1 hold for the
cochain complex of left A-modules rem 1, we have that
Hn((,C*)")
('C*").
Therefore, by Theo-
is finitely generated as left
A-module, which completes the proof. Remark 1.
all
Q.E.D.
In the Note to Lemma 1.1.1, we have observed that the
technical condition (TC) of Lemma 1.1.1 is equivalent to condition (TC') of the Note to Lemma 1.1.1.
Another way of writing
(TC') is as: (TC") n > 0
For every integer
such that if
A _ i l
A/ (tlA + ••• + ti_lA),
m
n
~-
~-
n
there exists an integer
is the quotient ring
then
I t.A. 1;:) (I A. 1) ~
m.:. 0,
(t.A. 1)' ~
~-
A _ = i l
Finitely Generated Ideal
751
I
i < i < r-l.
Another equivalent way of writing this condition is that, (TC'" ) n>O
For every integer
m> 0
such that, for all integers
in the ring
right
(=
that
A
l~i~r-l,
A.
proposition 4. tl, ... ,t r
i,
there exists an integer
Let
A
be a ring with identity and let
be an r-sequence of elements of two-sided) ideal generated by is I-adically complete.
technical condition to Lemma 1.1.1,
(TC)
A.
Let
{t , ... , t }. l r
I
be the Suppose
Suppose also that the
of Lemma 1.1.1 holds.
(By the Note
(TC) of Lemma 1.1.1 is then equivalent to
(TC') of the Note to Lemma 1.1.1).
(The technical condition (TC) can be eliminated if the elements (Le., i f t.t.=t.t., of the ring A commute r l J J l l,2,i,2,j ,2,r); see part (1) of the Rc:aark following this Proposi-
tl, ... ,t
tion) . Let
C*
and
D*
A-modules such that all integers
n,
be (z-indexed) cochain complexes of left n C
and
and let
plexes of left A-modules.
n D
are I-adically complete for
¢*: C* .... D*
be a map of cochain com-
Then the following two conditions are
equivalent (1)
Hn (¢*): Hn(C*) .... Hn(D*)
modules, all integers (2)
is an isomorphism of left A-
n.
H~{A/I,¢*): H~{A/I,C*) ""H~{A/I,D*)
is an isomorphism
752
Chapter 8
of left (A/I)-modules, all integers (l)~
proof:
(2) follows from the universal coefficients spec-
tral sequence; to show that (1).
n.
The proof is by induction on Choose
such that
'C* 'C
n
and and
'0* 'On
Assume (2); we must prove
(2)~(1).
r.
cochain complexes of left A-modules are free left A-modules, and such that
we have 'C*..,.C*
p*:
and 1*:
'0*""0*
homomorphism of cochain complexes of left A-modules such that Hn(P*)
and
n H (1*)
are isomorphisms for all integers
n,
and
such that there exists '¢ *:
'C*..,.' 0*
a homomorphism of (z-indexed) cochain complexes of left A-modules such that the diagram '!J2*
'C*
!J2*
>0*
('C*)A
and
('O)A
C*
tions of
'C*
Let and
'0*.
1
Then since
complete for all integers
n,
'C*
(1)
1
1
p*
is commutative.
) '0*
t 1
(' C* {'
C*
*
n C
be the I-adic compleand
On
are I-adically
we obtain a commutative diagram: '~*
;;. '0*
1
(' ¢*)A ;;.(' o*{' !J2*
1 0*
Finitely Generated Ideal
753
I
The composite of the left (respectively: right) column of the commutative diagram (1) the image, call it n H
is
p*
(respectively:
T*).
Therefore
Hn(l), of the diagram (1) under the functor
has the property that the composite of the left (respec-
tively: right) column is an isomorphism. the commutative diagram Hn (¢*)
Hn(l), we deduce that, to show that
is an isomorphism, it suffices to show that
is an isomorphism.
n C
and
On
free left A-modules, all integers theses of this Proposition, A,
are I-adic completions of n.
But then, by the hypo-
(tl, ... ,t ) is an r-sequence in the r
and by the technical condition (TC)
the hypotheses
of Lemma 1.1.1 hold.
of Lemma 1.1.1, we have that
c
quence for
n
Hn(,¢*A)
Therefore it suffices to prove the Proposi-
tion in the case that
ring
By diagram chasing in
and for
on,
Corollary 2.1 we have that
we have that
Therefore by the conclusion
(tl, ••• ,t ) r all integers
is also an r-sen.
Therefore by
n H~ (A/I, C*) "" H ( (A/I) 0 C*) ,
and
A
similarly for For
0*.
r == I,
the Proposition follows from Proposition 3
(following Prop. 2, several Examples, and Cor. 2.1) of Chap. 5. If r .:: 2, and we have proved conclusion (1)
for r-l, then consider
the map ( (A/t A)0 C*) l
-+
A
The cochain complexes
((A/t Al0 0*) • l A
(A/tlA) 0 C*, A
(A/tlA) H¢* integer tlC
n
r-l.
(A/tlA) 00*
and the map
A
obey the hypotheses of this Proposition for the (Notice that, by the technical condition (TC),
cn ,
is I-adically closed in
and therefore
(A/tlA) 9 C
n
A
is J-adically complete where
J
is the image of
I
in
A/tlA,
Chapter 8
754 all integers
n.
And similarly for
On,
all integers n.)
Therefore, by the inductive assumption applied to the ring (t +t A), ... ,(t +t A) and the ideal 2 l r l n is an isomorphism for we have that H ((A/tIA) 6Sl ¢*)
(A/tIA),
the sequence
J = I/tIA,
A
all integers
n.
But then by Proposition 3 of Chapter 5
equivalently, by the case A,
the ring sor in
and the ideal
of this Proposition) applied to since
tlA,
n C
jective in
Dn,
and in
all integers
n,
is an isomorphism for all integers
Remark:
is a non-zero divi-
tl
and the endomorphism "multiplication by
A
n H (¢*)
r = I
(or,
tl "
is in-
i t follows that
n.
Concerning the technical condition,
Q.E.D.
(TC), in Corollary
1.1 and in Proposition 4, (1)
(Le.,
If in Proposition 4 the elements l~i~j~r),
titj=tjti'
t
i
Ti -+t i ,
l~i~r,
power series in
where r
Z(Tl, ... ,T > r
Z-indexed cochain complex
7.
A
by
1"'"
is the ring of formal Then every
If
I' =
then for every left A-module Z{T , ... ,Tr)-modules. l C*
Consider
such that
Z(Tl, ... ,Tr)-module.
(T , ... ,Tr)Z(Tl, ... ,T ), l r have that M'I", M'I' as
"'~{T
(T , ... , Tr> -+ A I
(Proof:
variables over the integers.
left A-module becomes a
Lemma 3 that
;l,
commute
then this hypothesis can be
eliminated, and the proposition remains true. the homomorphism of rings
1
,
M,
we
Also, for every
of left A-modules, we have by
H~((A/(tlA+ ... +trA)),C*) T 'j(Z(Tl,···,T )/(Tl,···,T ),C*). r r r
Z(Tl, .•. ,T r ),
tl, ... ,tr
if necessary, we can assume that
by
Tl, ... ,T
Therefore replacing r
A =Z{T , ..• ,T ). r l
trivially, the condition (TC) holds for the ring completing the proof).
and
I
by
I'
But then, A=Z(Tl, ... ,T ), r
Finitely Generated Ideal (2)
, 1 ~i ~r, are i then the technical hypothesis,
If in Corollary 1.1 the elements
in the center of the ring
755
I
A,
t
(TC), of the Corollary can be deleted, leaving a true Corollary. (Proof:
¢:;Y(Tl, ... ,T ) -+A r
Let
rings with identity such that
"H!(T
i,
1 < i < r.
+ '"
Then re-
+ trA) ,0*)"
with
T) (Z(Tl,···,T )/(Tl,···,T ),0*)", r r r all cochain complexes 0* of left A-modules) (L
(all integers
¢ (T i) = t , i
"H~ (N(tlA
placing the left A-modules, the left A-modules,
be the unique homomorphism of
1"'"
in the proof of Corollary 1.1, we see that the proof of Corollary 1.1 goes through with this substitution throughout. 3
But Lemma
¢:Z(T , ... ,T ) -+A then l r completes the proof of Corollary 1.1 (in the case that we delete applied to the homomorphism of rings
the technical hypothesis (TC) in that Corollary, but assume instead that
tl, ... ,t
are in the center of the ring
r
A). Q.E.D.
The proof of the part (2) of the last Remark also proves Corollary 1.2.
Let
A
be a ring with identity and let
I
be
a finitely generated (left, right or two-sided) ideal in the ring
A.
Suppose that the ring
that there exist an integer I
that generate the ideal
two-sided ideal) such that ring
A. Let
r I
A
~
0,
with identity such that
and elements
t
l
, ... , tr
in
(as left ideal, right ideal, or
tl, ... ,t
Suppose also that the ring ¢ :;y (T l' ... , T r) ... A
as I-adically complete, and
r
are in the center of the A
is left Noetherian.
be the unique homomorphi sm
¢ (T ) = t , i i
1 < i < r.
Then let
0
f rings C*
be
a fixed z-indexed cochain complex of left A-modules, such that c i is I-adically complete, for all integers i, and let n be any fixed integer.
Then if
756
Chapter 8 (1)
Hn'T T) (;Z\Tl,···,T )/(Tl,···,T ),C*) ;Z'l""'r r r
is finitely generated as left (A/I)-module, then (2)
Hn(C*l
Remarks:
1.
Corollary 1.2 is an improvement on Corollary 1.1
(in the case that A),
is finitely generated as left A-module.
tl, ... ,t
r
belong to the center of the ring
since the (strong) hypothesis, that
r-sequence for the ring 2. "tl, ... ,tr
A",
"(t , ... , trl l
is an
has been deleted.
The full strength of the hypothesis, that belong to the center of the ring
A",
appears neces-
sary for the statement of Corollary 1.2 (since otherwise
~/T ~IZ,
1"'"
T) (;Z\Tl,···,T )/(Tl,···,T ),C*) r
r
r
does not in general
possess a natural structure as left A-module) • 3.
In Corollary 1.2, one can replace
";Z\T ,· .. ,T )" r l "cjl:;Z(T , ... ,T ) ->- A" r l
throughout with
"A(T , ... ,T )", replacing r l by the unique homomorphism: "A(T , ... ,T ) +A" I r identity that induces the identity on
A
(of rings with
and is) such that
T.
maps into
l
t , 1 < i < r. By Lemma 3, this will not affect the i percohomology group appearing in equation (1) of Corollary 1.2. (I.e., one can replace the percohomology group in equation (1)
of Corollary 1.2 by the canonically isomorphic group, HAn(T
1"'"
4.
T) (A(Tl,···,T )/(Tl,···,T ),C*». r r r However, very definitely, under the hypotheses
of Corollary 1.2, one
~
not replace the percohomology group
in equation (1) of the corollary with
"H~(A/I,C*)'" (unless
(t , ... ,t ) r l
is an r-sequence in the ring
A),
since
Finitely Generated Ideal when
(tl, ... ,t ) r
757
I
is not an r-sequence in the ring
H~(A/I,C*)
percohomology group
A,
the
is very different from
~(T T \ (Z(Tl,···,T )/(Tl,···,T ),C*). Z I'···' n' n n 5.
Can the technical condition (TC) in Proposition
4 and in Corollary 1.1 be deleted in all cases (even if tl, ... ,t
r
do not commute
in the center of the ring
elementwis~
A)?
or, respectively, are not
In the Remark following Proposi-
tion 4, we showed that this was the case, if in, e.g., Propositl, ... ,t
tion 4,
commute.
r
Studying that proof, we see
that we are led to study the "free ring" exists an r-sequence
t
tity with generators
tl,.··,t r ,
l
R
such that there
, ... , tr E R -- i. e., the ring with idenXijk
(l~k~i<j~rl,
Xkjkal£l···as£s all integers
s
~
1,
with the relations: l
each integer
s > 1.
It is not difficult to see that, if tity, and
(ul' ... ,u ) r
A
is any ring with iden-
any r-sequence in the ring
there exists a homomorphism of rings with identity that
cP (ti'
=ui '
1 < i < r.
A,
then
cp:R + A
such
It seems possible (but the negation
758
Chapter 8
also seems quite possible) ideal generated by
I = tl R +
that, if
(tl, ..• ,t ), r
+t R r
is the
then
(t , .•• ,t ) is an r-sequence for the ring R/\I. (It r l is certainly true, by the construction, that the first condition (1)
of Definition 1 of "r-sequence" holds), and that (2)
Condition (TC) of Lemma 1.1.1 holds for
A=R/\J..
If indeed (1) and (2) above hold, then the proof of the first part of the Remark following Proposition 4, would enable one to remove the technical condition (TC) from the statement of Proposition 4. It is not difficult to show that
is the ring
of non-commuting polynomials in denumerably many variables over the corresponding ring for the integer inductive effort to study that,
tlRAI
Therefore, an
(1) and (2) should focus
(left multiplication by
whether
r - 1.
on proving
t
) is injective in l has the induced topology in RAI. (*)
R/\I,
and
A similar effort to remove the hypothesis (TC) altogether from Corollary 1.1, would lead one to study a more complicated set of rings than
R.
If
A
is as in the hypotheses of Corol-
1ary 1.1 (deleting the hypothesis, .. (TC) "), then one needs a ring
5
together with a sequence
the completion by
(ul' •.. ,u r )
t
of
5
(ul' ••• ,u ) r
in
5
such that
with respect to the ideal generated
is such that
(ul' ... ,u r )
is an r-sequence, is
such that the technical condition (TC) holds, and is such that we have an epimorphism 1 < i < r.
4>:5
/\
.. A
Also, one needs that
of rings such that 5/\
removing (TC) in Proposition 4, one needs only such a homomor-
(*) Prop. 4 holds, even without (TC},for
any two-sided ideal I.
Finitely Generated Ideal phism
rjJ,
759
I
and does not need a "left Noetherian" assumption.)
The reason
rjJ
must be an epimorphism for affecting
an improve-
ment in Corollary 1.1, is that one needs to know that finite generation of
as left
sA-module
as left A-module.
is equivalent to finite generation of
«1) and (2) are always isomorphic canoni-
A
cally as left S -modules by Lemma 3. cp:SA -+A
If the homomorphism
is surjective, then "finite generation as left SA_ mod -
ule" becomes equivalent to "finite generation as left A-module".). (Of course, trivially, if
A is a ring, complete with re-
spect to the right ideal generated by an r-sequence such that exists a left-Noetherian ring
S,
tl, ... ,t , r
complete with re-
spect to the right ideal generated by an r-sequence S
such that
obeys the technical condition (TC), and such that
there exists an epimorphism that
cp (u ) = t
i
ul, ... ,u ' r
i ,
1
~
i
~
r,
rjJ:S -+A
of rings with identity such
then the ring
A
also obeys the
hypothesis (TC)). 6.
Of course, the hypotheses in Theorem 1, in Corol-
lary 1.1 and in Corollary 1.2, that "the ring
A
is left
Noetherian" can be eliminated, if we were to modify the statement of the Theorem and Corollaries appropriately.
However,
such a modification is rather bulky and awkward in the case when the ideal
I
is not simply generated.
some finite sequence
(tl, ... ,t ) r
(One has to fix
of elements of
I
that gen-
Chapter 8
760
erate
I.)
The length of the necessary hypotheses to eliminate
the indicated quoted hypothesis increases with the length
r
of the sequence. A strengthening of Proposition 4, analogous to the strengthening, "Corollary 2.1" of "Corollary 1.1", can be stated, in which
"Hn(T T ) (;l.(Tl,···,T )1 (Tl,···,T ) ,C*)" replaces Z 1'···' r r r "H~(A/I,C*)"; (or, one can work with "Z[Tl, ... ,Trl" in lieu
of
"Z(Tl, ... ,T )".) One has to assume that tl, ... ,t r r mute, but one removes the very strong hypothesis that is an r-sequence for the ring
A".
com-
We state this
result as a Corollary to proposition 4. Corollary 4.1.
Let
A
be a ring with identity and let
a two-sided ideal in the ring exists an integer
r> 0
A.
I
be
Suppose also that there
and elements
t , ... , tr that generate l the ideal I as right ideal such that the elements tl, ... ,t r COITUllute in the ring A, (Le., such that to' to =to· to, J
1
l~i,j~r).
Let
¢:Z[Tl, ... ,Trl +A
J
1
be the unique homomorphism
¢(T ) =t , l
of rings with identity such U,at Let
C*
and
0*
lexes of left A-modules, such that complete, all integers
n.
Cn
and
on
are I-adically
Let
p*: C* .... 0* be an arbitrary map of cochain complexes of left A-modules. Then the following two conditions are equivalent
integers
n.
Finitely Generated Ideal (2)
H~[T fL.
1"'"
761
I
T ](;?[Tl,···,T ]/(Tl,···,T ),p*): r
r
r
->Hn[T T 1 (;? [Tl,···,T l/ (Tl,···,T ) ,0*) ;? l " " ' r r r is an isomorphism, all integers
n.
Proof: By means of the ring homomorphism q,:;?[Tl, ... ,Tr]-+A, n C and on are ;?[Tl, ... ,Tr]-modules, all integers n. Since n C and On are I-adically complete, Cn and on are also ;Z(Tl, ... ,Tr)-modules.
If
I'
Tl,···,T r
in ;Z(Tl, ... ,T r ),
I
and
by
I'
tl, ... ,t r
is the ideal generated by then replacing
by
Tl, ... ,T
;Z(T , ... ,T ), r l if necessary, we can
r
by
, 1 < i < r. But i then the hypotheses of Proposition 4 all hold (the technical
assume that
A =;Z(T l ,··· ,T r ),
I = I' ,
A
Ti = t
condition (TC) not being needed by the first part of the Remark following Proposition 4).
Therefore, by Proposition 4, condi-
tion (1) of this Corollary is (2' )
~(T
-7.
an(T -7
1"'"
1"'"
eq~ivalent
to:
T > (;7 ( T l , ... , T ) / (T l , ... , T ), p *) : r r r T) (;Z(Tl,···,T )/('l'l,···,T ),C*) r
r
r
n --+H71 (T T) (;Z(Tl,···,T )/(Tl,···,T ),0*) 1"'" r r r is an isomorphism, all integers
n.
But by Lemma 3, equations (2) and (2') are equivalent.
Q.E.D.
An immediate consequence of Corollary 1.2, in which statements about ordinary cohomology replace percohomology, is Corollary 1.3.
Let
an ideal in the ring
A A.
be a ring with identity and let Suppose that the ring
A
I
be
is I-adically
Chapter 8
762
complete, and that we have an integer tl, ••. ,t r
in
I
r >0
that generate the ideal
and elements I
such that
t , .•. ,t are in the center of the ring A. Let 1 r CP:Il[T1, ... ,T r ] +A be the unique homomorphism of rings with rp (T i) = t , i is left Noetherian.
identi ty such that ring
A Let
C*
plex of left
7 [T , i-or:!. 1
••• , T]
i,jEIl,
i>O.
Let
n
(1)
Hn+i(D~)
then (2)
r (Il [ Tl ' ... , Tr
be any fixed integer. l.
for
i, let
be the cochain com-
D'l'
l.
(A/I)-modules, such that
oj - 'T
]/ (
Tl' ••• , Tr ) ' Cj ) ,
Then if
is finitely generated as left (A/I)-module,
0':' i.:. r,
Hn(C*)
the fixed integer Proof:
is I-adically complete for all inte-
Then for each integer
i.
Suppose also that the
be a fixed (Il-indexed) cochain complex of left
A-modules, such that gers
1 < i < r.
is finitely generated as left A-module, for n.
We have the second spectral sequence of percohomology, Il[Tl,· .. ,T r ] p Tor-q (Il [TI, ..• ,T ]/ (Tl, ••• ,T ),C ) r r q ==I> HfJ+[T T ](.z[Tl,···,T ]/(Tl, .. ·,T ),C*), .l 1"'" r r r
for which
By definition of
all
p,qEIl,
Also, by Lemma 2,
IEP,q 1
01, q
~
=0
P 'EP,q Dq' 2
we have that 'EP,q 1
= HP(D*) q ,
O. if
q~r+l
(or
q
<
-1) .
Therefore,
Finitely Generated Ideal
763
I
from the general theory of spectral sequences, since the ring A
is left Noetherian, to prove that the n'th group of the
abutment is finitely generated as left A-module, it suffices to prove that 'E~,q
is finitely generated as left A-module for
D~q~r.
p+q=n,
of the Corollary.
But the latter is exactly hypothesis (1) Therefore the n'th group of the abutment is
finitely generated as left A-module, i.e.
H~[T
(1' )
fL.
1"'"
T 1 (nTl,···,T l/(Tl,···,T ),C*) n n n
is finitely generated as left A-module.
But, by Lemma 3, the
percohomology group in equation (1') is canonically isomorphic ~(Tl,
to the corresponding percohomology group with replacing 1.2
Z[TI, ... ,Tnl.
... ,Tn)
Therefore equation (1) of Corollary
holds, and therefore by Corollary 1.2 we have that equaQ.E.D.
tion (2) of Corollary 1.2 holds. Remarks 1. with
In Corollary 1.3, one can replace
";r(TI, •.• ,T n )",
"A[Tl, •.• ,Tnl"
or
~[Tl'
... ,Tnl
"A(TI, ... ,T n )"
according to one's preference. The Corollary remains valid, R i since by Lemma 3 Tor (R/ (TIR + ... + T R),C ), all integers q
q, i,
q
~
is independent up to canonical isomorphisms of
0,
R=Z[TI,.··,T n ], 2.
r
If
Z(TI, .. ·,T n ), (tl, ... ,t ) r
A[TI, ... ,TnJ
or
A(TI, ... ,T n ).
is an r-sequence in the ring
A,
in Corollary 1.3 one can define .
A
~
l
.
D~=Tor.(A/I,CJ),
all integers
i,j
with
(since then, again by Lemma 3, this definition of
i>O
D~
~
coincides,
up to canonical isomorphism, with the one given in the Corollary) .
Of course, if
(tl, •.. ,t ) r
is not an r-sequence, then
764
Chapter 8
one cannot do this . Of course, there is a statement analogous to Corol-
3.
lary 1.3 in the situation of Corollary 1.1, with percohomology over
A
replacing percohomology over
Corollary 1.3'.
Let
A
respect to an ideal
~
[T , ... ,Trl. l
be a ring with identity, complete with
I,
such that
I
is the right ideal gener-
ated by an r-sequence (t , ... ,t ) for the ring l r ger >0.
Suppose that the ring
the technical condition Let
C*
c
such that let
n
Namely,
A
A,
r
an inte-
is left Noetherian, and that
(TC) of Corollary 1.1 holds.
be any fixed cochain complex of left A-modules i
is I-adically complete, all integers
be a fixed integer.
i,
Define cochain complexes
and D~ 1
of
left (A/I)-modules by requiring that .
A
1
1
.
D~ = Tor. (A/I}:]) ,
all integers
Then if, for the fixed integer (1)
0:" i
:.. r, (2)
H
n +i (D~)
i, j
wi th
i > O.
n,
is finitely generated as left (A/I)-module,
1
then Hn(C*)
is finitely generated as left A-module.
(The proof is similar to that of Corollary 1.3.) An amusing application of Corollary 1.3 is given by the following four examples. Example
1.
Let
identity, let
t l , ... ,t r integer
A
I
be a Noetherian commutative ring with
be an ideal in the ring
A
and let
be a set of generators for the ideal ~O).
scheme over
Let X
X
I,
(r
an
be an arbitrary locally Noetherian pre-
(i.e., a prescheme that is locally isomorphic to
spectra of Noetherian rings).
Then we have the completion
Finitely Generated Ideal
Ox
of the structure sheaf
765
I
with respect to the ideal
I,
which is a sheaf concentrated on the closed subset: Y = xspe~ (A) Spec (A/I)
(~I) -modules over we would say,
of
Let
F
be any coherent sheaf of
(In the language of "formal schemes",
X.
"let
X.
F
be any coherent sheaf of modules over the
structure sheaf of the formal prescheme Let
M
i> 0,
u
such that
I
U
'
M = O.
Then, for each in-
consider the assignment: A
U'V'v>Tor (M,f(U,F», i
(1 )
where
Y) ").
be any finitely generated A-module such that there
exists an integer teger
(y,O~II
U
runs through the affine open subsets of
X.
Then the
presheaf (1), restricted to the open base consisting of affine open subsets of
X,
Ox-modules over
X -- in fact, is a coherent sheaf of
Ox
is a sheaf, and is a coherent sheaf of
x S (A/lu)-modules over the prescheme, Spec (A) pec
(Y, Ox
x S ec (A/l u ) ). (Notice that we are speaking here of a Spec (A) p .
coherent sheaf over the structure sheaf of a prescheme, rather than of a coherent sheaf over the "completed up" structure sheaf of a formal prescheme). Proof: ideal
Let I.
tl, ... ,t r
be a finite set of generators for the
By induction on
j,
o~ j
~
r,
I claim the assertion
is true if there exists an integer
B>0
such that
B t j +1 • F = •••
then
tk • F = 0,
B
+ tr • F = O.
and therefore
IrB. F = 0,
If
j=O,
whence
modules over the sheaf of rings
F
B
is a coherent sheaf of and therefore is a
Chapter 8
766
°-
coherent sheaf of
modules over
x
Then the assertion
X.
follows from the elementary facts that, if Noetherian algebra over U
A
(in the application,
any affine open subset of
generated A-module and the application,
N
X),
i,
N=r(U,F»,
M
M
is a finitely
A
then
Tori(M,N)
isafinitely
i > 0 -- this is proved by in-
using the long exact sequence of Tor's associated
to any short exact sequence some integer
then if
R=r(U,Ox),
is a finitely generated R-module (in
generated R-module, all integers duction on
R is a commutative,
s
~
0,
0 .... M' .... As .... M .... 0
of A-modules for
(such a short exact sequence exists since
is finitely generated as A-module)--and the fact that
A A Tori(M,Nf)""Tori(M,N)f' ules
M,
all integers
all R-modules i >0
all fER, all A-mod-
(this latter fact not even re-
quiring any Noetherian assumptions on following from the fact that
N,
Tor~1
A
and
R,
but just
commutes with direct limits
over directed sets.» Assume the assertion is established from some
o 2. j
< r - 1.
To prove the assertion for
B'
that, if
B'
tj+2 • F = ... = tr
• F = 0,
j + 1.
j,
We must show
then the pre sheaf (1) on the
open base consisting of affine opens is a coherent sheaf on that base over the sheaf of rings lU·M=O, of
X,
I
u
A • Tor. (M, r (U,F» 1
= 0,
Since all affine open subsets
U
and therefore clearly the presheaf (1) is a presheaf of
modules over
O~l /lu • O~I "" 0X/lu • OX.
Therefore it suffices
to prove that the presheaf (1) on the indicated open base, (which is therefore a presheaf of base on
Xl,
Ox - modules over that open
is both a sheaf and coherent over
show that, for every affine open subset
U
of
OX. X,
I.e., to if
Finitely Generated Ideal R=r(U,Ox)' (2)
every
and
N=r(U,F),
A
then
is finitely generated as R-module and for
Tori (M,N)
fER,
767
I
the natural map is an isomorphism
(3)
for all integers
i > O.
ated module over
RAI,
B'
(Notice that
N
is
a finitely gener-
and that we know that
B'
tj+2 ' N = ... tr ON = 0;
and that by the inductive assumption, we
know that equations (2) and (3) are true if there exists an integer
C>0
C
such that
tj+l
tj+l-torsion element in
N.
°
Let
N = 0) •
Then since
ated module over the Noetherian ring
N o N
RAI
ing Example 4 below for the proof that
be the set of
is a finitely gener(see Remark 2 follow-
R0
I
is Noetherian) it
is likewise finitely generated follows that the submodule N o AI as R - module. Since NO is a tj+l-torsion module, there exists an integer j
C> 0
+l~k~r,
such that where
C
t j + l No = O.
D=sup(B',C).
But then Therefore by the
inductive assumption, equations (2) and (3) hold if we replace N
with
No'
Throwing the short exact sequence
o -+ No
-+
N -+ N/N
0
-+
0
of A-modules through the exact connected sequence of functors: A
(Tori(M, »i>O' hold for N
No'
and using the fact that equations (2) and (3) we see that, to prove equations (2) and (3) for
it suffices to prove them for
N/N . o
I.e., we're reduced to
proving equations (2) and (3) in the case that generated
If I
But then
module with no non-zero u
NI = N/tj+IN
N
is a finitely
tj+l-torsiono 1\1
is a finitely generated R
-module,
768
Chapter 8
and
where
D
= sup (u, B')
,
so that by
the inductive assumption, equations (2) and (3) hold with replacing
N.
Nl
The long exact sequence of Tor's associated to
the short exact sequence of A-modules
is the long exact sequence: U
d i +1
A
A
t'+ l
A
di
--"'> Tor. (M,N)~>Tor. (M,N) ...... Tor. (M,N )--=-;>
l
1 1 1
Since
1
U
' M = 0,
we have that
t
U j+l
endomorphism, "multiplication by A
Tori (M,N)
t
. M = 0,
u " j+l
i > O.
is zero, all integers
and therefore the
of the A-module Therefore the above
long exact sequence of Tor's yields the short exact sequences
i ,:,1,
all integers A
Tori_l (M,N) i,.:,l,
from which it follows immediately that
is finitely generated as R-module, all integers
and also (by induction on
that equation (3) holds.
i)
This completes the inductive proof, that the presheaf (1) on affine opens is a coherent sheaf of
0x/1u. Ox - modules over
Y . Example I
2.
Let
B
be any commutative ring with identity, let
be any ideal in the ring
O~ = l,im(0wl1jOw)'
B,
let
W= Spec (B) ,
let
a sheaf concentrated on the closed subset
j,:, 0
of
(I = 0)
W
(let
Y
denote this closed subset).
any quasicoherent sheaf of (either over
X,
and let
F
OW-modules, or .
~1
= G· = Itm(G/1J j":'O
• G).
Then
Let
G
be
~1-mOdUleS)
F is concen-
Finitely Generated Ideal trated on the closed subset
Y
of
Hi(W,F)=Hi(Y,FIY)=o,
(1)
X,
769
I
and
all integers
i>l.
(This is of course very well known, and fairly trivial.
We in-
clude a proof for completeness.) proof:
Let
m
be any finite set of affine open subsets of
such that the union is (2)
W.
W
Then we show first that
~i(m,W,F)=O,
i>l.
v
v '
In fact, C* (m ,W,F) = Ij,m C* (ur,W,G/IJG). j.:=:O
Also, the mappings in the inverse system of which the inverse limit is taken are epimorphisms. of Chapter (3)
3,
we have the short exact sequence
0+ [lj,m l Iii-l(m ,W,G/IjG)] +i'li(UI ,W,F) j.:=:.O V·
+
all integers sheaf of
Therefore, by Corollary 1.1
.
[l.im Hl(UI ,W,G/IJG)] j.:=:.O i> 0.
+
0,
But the sheaf
is a quasicoherent
Ow-modules over the affine scheme
collection of affine open subsets of W.
G/IjG
X
W,
and
i >
O'
Also, from equation (4), when
jr
(W,G/IjG),
i = 0,
is a
such that the union is
Therefore
=
UI
the map
°
i = 0.
Chapter 8
770
is an epimorphism, all integers
j::. 0,
so that
(5)
Equation (4)
for
i> 1
and equation (5) plugged into the short
exact sequence:; (3) imply equation (2). Next, noting that the set of all finite collections
X
open subsets of sets of
X
of
ill
the elements of which are affine open sub-
such that the union of
ill
X,
is
is cofinal in
the eech sense, and passing to the direct limit over such ill, we obtain that (6)
lii(W,F) = 0,
Replacing
all integers
W by any affine open subset in
larly, for every affine open subset (7)
i> 1.
vi H (V,F) = 0,
V
Finally, let
X
of
we have simi-
W,
that
i> 1.
be the set of all affine open subsets
the topological space topology of
all integers
V
W,
X.
Then
V
V
of
is an open base for the
closed under finite intersections.
By Theorem
5.9.2., pp. 227-228, of [G], it follows that
(8)
i
vi
H (W,F)"OH (W,F),
all integers
i.
Equations (6) and (8) imply that H
Since also
i
(W,F) F
=
0,
i > O.
is concentrated on the closed subset
Y
of
W,
Finitely Generated Ideal
771
I
These two equations imply equation (1). ExampLe 3. let
X
Let
A
Q.E.D.
be a commutative ring with identity and
be a locally Noetherian prescheme over
be any finitely generated ideal in the ring let
tl, ... ,t
ideal
I.
F
A.
Let
Let
r>
°
I
and
be a sequence of elements that generate the
r
Let
F
be any coherent sheaf of
the topological space let
Spec (A) .
X
°
AI
X - modules over
(in the language of "formal schemes",
be a coherent sheaf of modules over the structure sheaf
of the formal scheme:
I
AI Y), (Y,Ox
Let
U
Y
is the closed subset
be a fixed open subset of
Let such that
CP:il [T l , ... ,Trl -+A cP
each integer
where
where
m ~ 0,
of
X).
Y.
be the unique ring homomorphism
1 < i < r.
(T ) = t , i i
"I = 0"
Then by Example 1 above, for
the assignment:
W runs through the set of all affine open subsets of
X,
is a coherent sheaf of modules over the structure sheaf of the (Where
prescheme
l~i~r,
"A",
"Ti"
"I",
M=,l[Tl, ... ,Trl/(Tl, ... ,Tr)'
ger
m,:,O,
replaces
let
".". [T l' ... , mlr 1" fL.
"ti'"
replaces
"(Tl, ... ,T r )"
and
u=l).
replaces
For each inte-
TO~[Tl,···,Trl(il[Tl, •.. ,Trl/(Tl, ... ,Tr),F))
denote this coherent sheaf of
(Ox/I)-modules over
Suppose also that the topological space pact and that the ring fixed integer such that
A
is Noetherian.
Y
Y.
is quasicom-
Then, if
n
is any
772
Chapter 8 is finitely generated as
(A/I)-module,
02i2r,
then Hn(Y,U,F)
(3)
is finitely generated as
fixed integer Proof:
A-module for the
n.
First, I claim that there exists a covering
of
ill
Y
(in the sense of [P.P.W.CJ, Chapter I, pg. 129), the elements of which are affine, such that
is finite, and such that
ill
[P.P.W~J
is a refinement (in the sense of covering
{Y,U}.
In fact, since
Y
pg. 128, line 4) of the
is a quasi-compact and
locally Noetherian prescheme, so is the open subset Therefore there exists a finite collection subsets of ill',
Y
such that
Y
ill'.
intersections of elements of ill"
ill'
Then
U
Let
Y.
of affine open
of
Y
can be written
ill" = {all finite non-empty
ill'}.
ill'" is a covering of
Chapter I, pg. 127),
Let
ill III = all elements of
ill'"
Y
(in the sense of [P.P.W.CJ,
is finite and every element of
is an open subset of a Noetherian affine scheme. induction on the finite set E E ill III
[P.P.W~.l,
illE
ill '"
U['''
By decreasing
ordered by inclusion, for
we define a finite covering (in the sense of
Chapter I)
Having defined fine
of
that cannot be written as unions of strictly smaller ele-
ments.
each
U
is the union of the elements of
and such that the open subset
as a union of elements of
ill
illE
ill , E
of
E
for all
by affine open subsets of E'Eill lll
to by any finite covering of
such that E
E~
E',
E. de-
that is a refine-
ment (in the sense of [P.P.W.C.], Chapter I, pg. 128, line 4) of H smaller elements of
cannot be written as a union of strictly ill
O
'
where
illO ={F
n E:
F E ill E'})'
for
Finitely Generated Ideal all
I) ill
ill = U ill . EEill E is a finite set, and is a covering ([P.P.W,CJ, Chapter
E' E ill '"
Then
ill of
773
I
Y
E~
such that
E'.
Then define
the elements of which are affine opens, and such that
is a refinement ([P.P.WCJ, Chapter I, pg. 128) of the covering
{x,u}. paper,
(Note:
This construction is similar to one used in the
"On a Conjecture of Andre Weil", [CAW,], Amer. J. of Math.,
Chapter I, in proving that combinatorial cohomology of sheaves forms a system of derived functors). Next, let (4)
E* = C* (ill, (Y,U) ,F),
as defined in [P.P.WC.l, pg. 128, lines 22-26.
Then
Ei
is a
(finite) product of I-adically complete A-module3, and is therefore
I-adically complete, iE;y.
=
Also, for all integers
i,
j
~
0,
:7[T, Tor. 1 ... ,Tl( r J' [ T , ... , T l/( T , •.. , T ) , E j) . l r r l l
(This is so, since the covering the functor
ill
j G'VU> C (ill , (Y, U) , G) ,
of abelian groups on
Y
is finite, and therefore (from the category of sheaves
into the category of abelian groups)
is the finite direct product of functors of the type: G'VU>f (Wi'G),
i E S,
where
affine open subset of
Y.
is a finite set, and
S
Y,
"Cj(ill,(y,U),
)",
"f(W , )" i
replacing the func-
w i ·lS an a ff'lne open su b se t a f
h were
and this latter assertion follows from Example 1.)
then, since the elements of is quasicoherent over
is an
Equation (5) therefore follows from
the corresponding equations with tor
Wi
ill
(O~I) iY,
But
are affine open, and since and by Example 1 the sheaves
F
Chapter 8
774
TO?[Tl,···,Tnl(;l[Tl, ... ,T 1/(Tl, ... ,T ),F) r
1
0x/I. Ox'
are coherent over
r
we have, by ([P.P.W.c.l, I. 6, Theoj~O,
rem 7, pg. 152), for all integers
(7)
that
Hj (y,U,TO~ [T l ,·· ..,Trl (;l [T ,.· .,Trl/(T , •.. ,T ) ,F) l r l
""Hj(TO~[Tl,···,Trl(;l[Tl, ... ,T 1/(Tl, ... ,T ),E*)). r
1
(Here we are using the fact, for
W Em,
since
r
W is affine
open, we have that j H (W,F) = 0,
all integers
Hj (W,Tor/ [T l ,·· .,Trl
= 0,
all integers
j
j
~ 1,
(d'
[T , ... ,Trl/(T , ... ,T ) ,F)) r l l
~
1.)
(The second of these assertions follows from Example 1, since by Example 1
Tori;l[Tl,···,Trl (;l[Tl, ... ,Trl/(Tl, ... ,Tr),F)
coherent over the structure sheaf of the prescheme and
W is affine open in
Y.
A,
E*
the ideal
(in lieu of
I, the integer
of elements in the ring lary 1.3 above.
I
(Y, (Ox/I)1 Y)
The first of these assertions
follows from Example 2 above) of A-modules
is
But then the cochain complex C* r >0
in Corollary 1.3), the ring and the sequence
t
1
,··· , tr
obey all the hypotheses of Corol-
The conclusion of Corollary 1.3,
(that equa-
tion (1) of Corollary 1.3 implies equation (2) of Corollary 1.3), and equations (6) and (7) above show that, equation (2) implies equation (3), completing the proof of this Example. (in the notations of Corollary 1.3, To r~
D~= 1
[T l' ••. , T r 1 (z [T l' ... , Tr 1I (T l' ..• , Tr) , E *) )
Finitely Generated Ideal 4. let
Let
A
775
I
be a Noetherian commutative ring with identity and
be a Noetherian prescheme over Spec (A).
X
any ideal in the ring
A
Y = X Specx (A) Spec (All)
Let
I
be
such that the prescheme is proper over
(The word
Spec (All).
"proper" implies "of finite presentation").
The (I = 0) . palr
is a sheaf concentrated on the closed subset: of
Let
X.
(Y,OAxI
ly )
Y
denote this closed subset.
. t'lng conS1S
0
f th ioglca ' 1 space e topo
F
Y
and
O~I
is a formal prescheme.)
be any coherent sheaf of
(OA I) _ modules over the
this "sheaf of topological rings" Let
(Then the
topological space
X
X
(or equivalently over
Y).
(Then
F
is
a coherent sheaf of modules over the structure sheaf of the formal pre scheme
AI
(y,Ox
IY)).
Then Hn(Y,F)
is finitely generated as
all integers Proof:
Taking
U
(AAI)-module,
n > O.
to be the empty set in Example 2 above, it
suffices to prove that each of the sheaves: F. =TO?,[Tl,···,TrJ (;r[Tl, ... ,T J/(Tl, ... ,T ),F), 1
for
r
1
O.s. i .s. r,
r
have finitely generated cohomology groups as
(A/I)=modules over the topological space replacing
Y.
"A", "Ti"
But, by Example 1 replacing
we have that the sheaves
lit.
II
1
F.
1
are
776
Chapter 8
coherent sheaves of over Spec (A/I), H
j
y.
Since
Y
is proper
it follows that is finitely generated as
(Y ,F. ) ~
all integers
0y-modules over
j,:::,O,
all integers
i
with
(A/I) -module, O.:':i~.r,
as re-
quired.
Q.E.D.
Remarks. 1.
Of course, a special case of Example 4 is the one
in which
is proper over Spec (A),
X
which is of course very
well known. 2.
In the course of proving Example 1, we used the
fact that, if and if
I
B
is a Noetherian commutative ring with identity
is any ideal in the ring
Noetherian.
B,
then
BAI
This is of course very well known.
be deduced very easily as a Corollary of
is also
But it can also
Lemma 1.1.1 at the be-
ginning of Chapter 5. Proof:
A consequence of that Lemma is that, if
B
is a
Noetherian commutative ring with identity, then so in
B(T),
the ring of formal power series in one variable over then by induction on the integer But if
I
is any ideal in
by r-elements, then
3.
BAI
B,
and if
so is I
But
B(T ,··· ,T r ). l
is generated as ideal
is isomorphic to a quotient ring of
The proof of the Lemma 1.1.1 of Chapter 5 proves
slightly more (by induction on (1)
r,:::, 0,
B.
Lemma.
Let
B
r):
be a (not necessarily commutative)
ring with identity that is left Noetherian, and let
I
ideal in B
and a set
tl, ... ,t
r
such that there exists an integer of elements of
I
that generate
r >0 I
be an
as ideal and
Finitely Generated Ideal such that the right ideal generated by
777
I
tl, ... ,t
i
is a two-
(t ,··· ,t ) r l obeys condition (1) of Definition 1 at the beginning of this sided ideal,
chapter).
(Le., such that the sequence
Suppose that the ring
BII
Then
1
B
is left Noetherian iff
B
is I-adically complete. is left Noetherian.
That Lemma has the immediate Corollary
(2)
Corollary.
Let
B
be a (not necessarily commutative) ring
with identity and let
I
be an ideal in the ring
left Noetherian, and if there exists an integer sequence I
tl, ... ,t r
of elements of
B
B. r > 0
If
B
is
and a
that generate the ideal
and such that the right ideal generated by
two-sided ideal, all integers the sequence
(t , ... ,t ) r l
i,
1 < i
{tl, ... ,t } is a i (L e., and such that
obeys condition (1) of Definition 1
at the beginning of this chapter), then the I-adic completion BtU
of the ring
I
is also a left Noetherian ring.
By the Lemma applied to the ring it suffices to prove that
(BAllI
BAI BAI)
But this letter ring is isomorphic to Noetherian since Remark.
B
and the ideal
(Proof: I . BAI,
is left Noetherian.
B/IB,
which is left
is left Noetherian) .
In the course of proving Example 3, we needed to know
that, in the notations of Example 3, i f F is a coherent sheaf AI and if W is an affine open subset of Ox - modules over X, of
X, (1)
then Hi (W,F) = 0,
i > 1.
Of course, this is actually covered in Example 2. in Example 2, equation (1) is proved, not for
F,
However,
but for
therefore to make use of Example 2, we must know that
F = FAI.
778
Chapter 8
Since
F
is coherent over
°X
AI
it is equivalent to show
'
that: 1.
If
M
is a finitely generated module over the
Noetherian commutative ring
B,
and if
I-adic topology for some ideal ly complete. AI
B=
r (W, OX
),
Ai
where
W
I = ideal in
since
B,
F
is complete for the then
M=
M
is I-adical-
r (W, F) ,
generated by the ideal
B
is any affine open subset of
rank (the set of such Y
in
(In the appl ica tion, take
is the quotient of a free
of
I
B
AI
(OX
) Iw
X
I
in
such that
Flw
sheaf of modules of finite
W's forms an open base for the topology
is coherent over
0X
AI
)).
Observation 1., which is of course well-known, follows from Lemma 5 below.
(Note:
The proof of Lemma 5 is much easier in
the commutative case). Lemma 5. let
I
Let
A be a left-Noetherian ring with identity and
be an ideal in the ring
I-adically complete. and a sequence
A
such that the ring
A
is
Suppose that there exists an integer
tl, ... ,t r
of elements in the ring
A
r >0
such
that, (1)
For each integer
ideal generated by equivalent to say,
i,
1,::, i::r,
we have that the right
{tl, ... ,t } is a two-sided ideal. i "and such that the sequence:
(It is
obeys condition (1) of Definition 1 at the beginning of this chapter". ) Suppose also that (2)
There exists an integer
N> 0
1.::. i.::. r,
such that and
Finitely Generated Ideal (3)
There exists an integer
B> 0
779
I
such that
t. 'A.t~ct.A, J
1
Then, if have that Notes.
M
1.
12. i 2. r, right
M
J
is any finitely generated left A-module, we
is I-adically complete.
If the ring
A
is such that, for every integer
the left ti -adic topology on
ti-adic topology on
A,
A
i,
coincides with the
then trivially conditions (2)
and (3) above both hold. 2. ring
A,
Of course, if
tl, ... ,t r
are in the center of the
then condition (I), (2) and (3) above hold. 3.
If the left ideal generated by
the right ideal generated by
t.
1
coincides with
then conditions
I-
~i'
(I), (2) and (3) hold. Proof: r - 1.
By induction, assume the Lemma is true for the integer Observe that every finitely generated left A-module
has the property that the natural map: (since
M
M .... rJ'I
is surjective
is a quotient of a free left A-module of finite rank,
and is therefore a quotient of a complete left A-module). fore
M
diction.
n IhM = {O} • Let us reason by contrah>O Suppose the Lemma-is false for some finitely generated M.
Then let
that the Lemma is false for
Q
be a left A-submodule of M such
M/Q,
mal (among left submodules of
M)
A
Q
is left Noetherian, such a M/Q
and such that
Q
is maxi-
with this property. exists.)
(Since
Then replacing
M
if necessary, it follows that there exists a finitely
generated left A-module M,
There-
is complete iff
left A-module
with
M
M,
such that the Lemma is false for
but true for every proper quotient (left A-module) of
M.
Chapter 8
780
Then every proper quotient left A-module of cally complete.
n
D=
(1)
M
is I-adi-
If we let IjM,
then since
M
is not complete,
D t- 0,
j~O
and
MID'" " I .
Therefore every proper quotient module of
is a quotient module of
MID.
Therefore
D
must be a smallest
(in the sense of inclusion) non-zero left A-submodule of In particular, if D = Ad.
And
of
ID
M.
d
d
is any non-zero element of
D,
M.
then
is an element of every non-zero left A-submodule
is a left submodule of
D.
Therefore, since
a smallest non-zero left submodule of 10 =
M
M,
either
10 = 0
0
is
or
o. I claim that it is impossible that then there exists an element
10 = 0,
Then
At"d
At I d = O.
at I d let
t" E I
is a non-zero left A-submodule of In particular, there exists
t = at ".
=
(In fact, if
ID=O.
a EA
such that 0,
t"d t- O.
and therefore
such that
d
Then
t EI
and
td = d, whence (1 - t) • d = O.
But the element verse
u = 1
(1 - t)
of the ring
+ t + t 2 + ...
Therefore
d=u' (l-t) 'd=u'O=O,
A has the two-sided in-
Finitely Generated Ideal a contradiction, since of
d
781
I
was chosen to be a non-zero element
D. Therefore ID={O}.
(2)
I _ = (tlA + ... + tr_lA) r l
The ideal
theses of this Lemma, and the ring plete.
obeys all the hypo-
A is (Ir_l)-adically com-
Therefore by the inductive assumption every finitely
generated left A-module, and in particular cally complete.
n
j.:::.O r-l I f I;_lM,/-O
M = 0.
for all
j.:::.O
then
I;_lM:::lD,
n I j IM:::l 0 '/- 0, a contradiction. j.:::. ran integer jo .:::. such that that
°
tion on
n,
(4) ... t
in
:l::,i , ... ,i ::.r}, l n
Let For
S
n =
To prove for I
=
Therefore there exists
Lm
i =r
n
={t . . . . t.
°
A,
n.
11
1n
all integers :l
n> 0.
n-
all integers
the assertion is immediate. For i = r.
Assume true for
n - 1
n = 1, where
it is n > 2.
The induction assumption can be written:
and hypothesis (1) of the Lemma for
mES
n-l
be wri tten:
implies, by induc-
is the right ideal generated by
condi tion (1) with
n-l
so
that
In
(Proof: n> 0.
j.::.O,
°
Hypothesis (1) of the Lemma for
11
all
jo Ir_loM={O}.
(3)
{to
is (Ir_l)-adi-
Therefore
j
I
M,
I = tlA +
0
••
+ trA.
'T'herefore
i =r
can
782
Chapter 8
In = In-I. I
=1 L m A)' I
=
\mES _ n l
!
mES
m ( t lA + . . . + t A) r n-l
L
=
L m (A mES _ n l m t. A= l
mES _ n l l
Lm
I) =
I =
mES _ n l [,\' m'A , mES
completing the in-
n
duction. ) For any integer quences teger,
let
n::' 0,
(s l' ... ,s v' k , ... ,kv) l
be the set of all se-
n
where
v
is a non-negative in-
,sv,k l ,··· ,k v - l ~ 1,
s 2""
sl + ... + Sv + kl + ... + kv = n. (1)
T
of the Lemma for
i = r)
Then using the fact (by hypothesis that
I = I _ + trA, r l
equation (4)
can be rewritten:
L t ( sl' .•. ,s ,k , ... , k )ET v l v n r
(4' )
all integers
n>O.
two-sided ideal in module
M),
Let A
K={a,=A:
a'M=O},
Then
K
is a
(the annihilator ideal of the left A-
and by equation (3) we have
(5)
If
n> 1
and
(sl"'"
kl + ... +kv~jo' sl kl s2 k2 tr I r - l tr I r _ l Therefore,
if
Sv,k l , ... ,kv) E Tn"
then
Sv kv ••. tr I r - l
C
kl+· .. +k v Ir- l
C
jo I r _l
C
K.
Un=~sl,· .. ,sv,kl,· .. ,kv): kl + ... +kv<jo}'
then from equation (4'), we have:
(6)
and if
Finitely Generated Ideal
783
I
If
k
If also
(s 1"" ,sv,k l ,··· ,k v ) E Un'
Therefore
v-l < jo'
Also since
then
kl + ... + kv < jo'
Le.
sl + ... +sv+kl + .,. +kv=n
it follows that
sl + '"
+sv >n- jo'
and
(8)
kl + '"
Since also
it follows that there must exist an integer
1,:: i.:: v,
v-> 0.
i,
+kv < jo'
sl""'sv':: O, such that
and such that n-j s. > _ _ 0
(v
v
1
~
°
since
n.::l).
By equation (7)
so that equation (8) yields S.>~-l. 1 Jo
That is, if
n>l
then for every
there exists an integer
i
(Sl, ... ,sv,kl, •.. ,k ) EU v n
such that
1 < i
and such that
(9)
But then
sl kl s. 1 k. 1 s. k. s. 1 k. 1 s k 1- ) t 1 (I 1 • t 1+ I 1+ t VI v ) (t r I r-l'" t r 1- I r-l r r-l r r-l •.. r r-l
Chapter 8
784
s.
I c
{ t
r-
It ~A,
if
r
i >
s. r
~A
if
'
1)
c
I
r-
s. It ~ r
i = 1
substituting by equation (9) this inclusion into equation (6), and replacing
II
nil
by
"n]'
"
o '
we see that for
n >1
we have
that
nj (10)
I
0
By hypothesis integer
integer
+I
r-
1 . t n. A
r
+ t n A. r
(3) of this Lemma, with
B>0
all integers
c K
j = r,
there exists an
such that
i,
r - 1
l
we have that
Ir - l •
t~ =
But by hypothesis (1) for the tlA + ... + tr_lA = I - . r l
(tlA + ..• + tr_1A) •
Therefore
t~
B B (tlAt r + ... + tr_1At r ) ctA+ ••. +tA r
r
that is, (11) If
B = 0,
then replace
we can assume that
B
by
I
r-l
In fact, for
• tB • I r k = 0,
in equation (11).
Therefore
B > 1.
I claim, by induction on (12)
+1
k,
that for
k
~
0,
we have
kj B 0
c K + tkA. r
the assertion is trivial.
Assume that
Finitely Generated Ideal Equation (12) Equation I
(12) • t
r-l
is true for the integer for the integer
B • I r
'"'
I
• tB •I r
r-l
where
k > O.
To prove
In fact,
k + l.
(k+l)j B 0
k
I
ki-'0 B
• I
jo R
which by the inductive assumption,
which by Equation (10) c K+ t
for
n = B
B k (K + I t B . A + t • A) r-l r r r I
t B • A + t k + B • A, r-l r r
which by E qua tion (11)
C
K + t k • (t A) • A + t k + B . A r r r
completing the inductive verification of Equation But then,
k~O,
for I
we have that
(B + Bj k) j 0
which by Equation (10) with
0
n = B + Bjok
B+Bj k B+Bj k c K+ I • tr o . A + tr o. A r l =K+I
C
K
+
I
Bj k B+Bj k t B • (t 0 A)+t 0 A r-l r r r B
t r-l r
Bj k I
0
which by Equation (12)
+t
B+Bj k °A
r
'
(12)
.
786
Chapter 8 B+Bj k C K + (K + tkA) + t r
That is, for (13)
I
k
~
0
0
Recall also that (14)
we have that
0,
Bj +Bj 2 k
A
0
r
C K + tkA.
K
r
is the annihilator ideal of
M,
so that
K' M= {oL
From Equations (13) and (14) we deduce that, for every integer k
~
we have that
0,
.
1
.2
BJ 0 +BJ k 0
'McK'M+t
k k k 'A'M={O}+tM=tM. r r r
That is, for every integer (15)
k~O,
Bj +Bj 2k o . MC tkM. I 0 r
Therefore
n InMC n tkM. n>O Since also
k>O r
t~MC IkM,
all integers
n tkMc n InM. k>O r n>O Therefore
n tkM = n InM k>O r n>O But, by Equation (1) (1)
n InM n>O
= D.
k
~
0,
Finitely Generated Ideal
787
I
Therefore (16)
Next, recall that by hypothesis (3) of this Lemma applied to the integer N>0
i = r,
we have that there exists an integer
such that
(17)
t N • Ac At r
r
I claim, by induction on the integer
i.::. 0,
that
(18) In fact, for i
i = 0
the assertion is trivial, and for
the assertion is equation (17).
= 1
tion is established for the integer i + 1.
assertion for the integer
Assume that the asseri
where
i.::. OJ
to prove the
In fact, we have that
t N (i+1) A = tNtNiAC tNAt i cAt t i = At i + l r r r r r r r r'
completing the induc-
tive proof of Equation (18). Now let V={xEM:
V = (the tr -torsion part of
There exists an integer
Then I claim that
V
h >0
and
a EA
exists an integer Equation (19)
whence
then h > 0
a· x
~
V.
t
i = h)
h r
M.
h tr • x = O}.
In fact,
We must show that, if
In fact, since
such that
(for the integer
M.
i. e., let
such that
is a left A-submodule of
is obviously an abelian subgroup of x EV
M),
• x =
o.
x E V,
there
But then by
we have that
V
788
Chapter 8
as required. Therefore Since
M
Since
is a left A-submodule of
M,
as asserted.
is a finitely generated left A-module over the left
Noetherian ring m> 0
V
A,
and elements
xl' ... ' xm (; V
it follows that there exists an integer xl' ... ' xm E M
such that
there exists an integer
But then, for every integer h Ax. CA. t J r
1
j,
x. = J
.s. j .s. m,
h >0
such that
we have that
o.
Therefore hN tr
hN hN hN V = t r (Ax 1 + ••. + AX ) = t r • Ax 1 + ... + t r • Ax m = 0 m
We have shown that (19)
There exists an integer
We will now use Equations
(16) and
By Equation (19), since elements in
M,
V
C >0
such that
tCV ={o}. r
(19) to complete the proof.
is the set of all t -torsion r
it follows that, for the fixed integer
C 2. 0,
we have that (20)
If
xEM
and
th.x=O r
where
h2.C,
then
t C • x = O. r
By Equation (16), since the element
dE 0
is on the left side
of Equation (16), for every integer
n> 0
there exists an ele-
ment
Y EM n
such that
Finitely Generated Ideal d = t~ • Y
(21) Define
Z
n
C
n = t r Yn+C •
(22) 0= d - d
Since
789
I
t
n Z =d r n '
Then
all integers
And
n >0 •
= t n + l + C Y + + - t n + C Yn+C -- tn+c(t r Yn+l+c - y ) n+C r n I C
n::.- 0,
n + C >C
so by Equation (20)
(with
00
h = n + C,
But then t
Z
r n+l
-
Z
n
= tC t t C(t ) = O. - tC r rYn+C+l r Yn + C = r rYn+C+I - Yn + C
I. e.,
(23)
trzn+l = zn'
By Equation (22) for (24)
Zo
all integers n = 0,
n> O.
we have that
= d.
But the Equations (23) imply that k
zl E n t M, k>O r and by Equation (16) this implies that
Since
D = Ad
therefore there exists an element
a EA
such that
Chapter 8
790
Then d (1 - tra)· d
= t r z 1 = t r ad
= O.
Bu t the element
(1 - ta) E A r
admi ts the two-
u = 1 + (\a)+ (t a)2+ (\a)3+ ... + . . . r
sided inverse: A.
'
in the ring
Therefore d
= 1 • d = u • (1 -
a contradiction, since in the left A-module
t a)' d
d
r
= u • 0 = 0,
was chosen to be a non-zero element
M.
This contradiction completes the proof. Corollary 5.1. let
Let
A
be a ring with identity as in Lemma 5,
M be a finitely generated left A-module and let
submodule of logy of Proof:
M.
N
The quotient module A.
M
MIN
for the I-adic topo-
is a finitely generated module
N
Let
is closed in A
is I-adically com-
M.
be a ring as in Lemma 5 and let
any left ideal in the ring
A.
Then
Apply corollary 5.1 with
Example.
MIN
Therefore by Lemma 5
Therefore
Corollary 5.2.
Proof:
is closed in
be a
M.
over the ring plete.
Then
N
is closed in
J
M= A
and
J
be
A.
N = J.
Under the hypotheses of Lemma 5, each of the ideals
(tlA + .,. + tiA)
is a left ideal,
Corollary 5.2 is closed in
1
~
i
~
r,
and therefore by
A.
Theorem 1, Corollary 1.1, Corollary 1.2, Corollary 1.3 and Corollary 1.3' are generalizations of Theoremsl and 5 of Chapter 5.
Are there similar generalizations of Corollary 1.1
Finitely Generated Ideal of Chapter 57
791
I
The answer is, "yes", as is shown by the following
sequence of Theorems.
(In the situation of Theorem 1, Corollary
1.1, ... ,Corollary 1.3', there is a corresponding statement about inverse limits of cohomology.
We will label these "Theorem 6,"
"Corollary 6.1", ... , "Corollary 6.3'"
respectively.)
For the sake of completeness, in our sequence of Examples we also note the following well-known fact. Example 5.
The hypotheses and notations being as in Example 4,
suppose also that
X
a coherent sheaf
G
of
A
and that there exists
Ox - modules over
/\
as sheaves of h> 0
is proper over
Ox - modules over
X
such that
G/\ "" F
Then for every integer
Y.
the natural map is an isomorphism: Hh (X,G) Q A"I ~ Hh(y ,F) A
First, since
Proof:
H
n
(X,G) QA
/\I
""H
n
A where
1T:XX (A/\I) A
in which Let
A
~X
is the projection, we reduce to the case
is I-adically complete.
tl, ... ,t r
be a set of generators for the ideal
if there exists an integer assertion is true.
n >0
(Since then
the ideal generated by
t 2 ,··· ,tr
tl-torsion subsheaf" of
G,
X.
Then
T
n
then the
tlG = 0,
in the ring
where A,
Next, let
and thereT
be "the
i.e. , the subsheaf such that r (U,G),
all open sub-
is a coherent subsheaf of
Ox-modules
of G over X, and there exists an integer n>O such that (Proof:
Let
Ul' ... 'U
h
I.
First notice that,
GAl = d'Ir - I,
r(U,T) = the tl-torsion in the A-module of
r.
such that
fore the inductive assumption applies).
U
),
A
The proof is by induction on the integer
sets
/\ I
(Xx (A
n
tlT=O.
be a finite set of affine open subsets
792
of
Chapter 8 X
the union of which is
X.
f(U.,T) = U J i>O f(U.,G) .... r(u.,G)], the union of
Ker[(multiplication by
Then
J
J
an increasing sequence of submodules of the finitely generated module
f(Uj,G)
r(Uj,T)
over the Noetherian ring
is finitely generated as
f(Uj,Ox),
whence
r(u.,Ox)-module and there n. J tlJf(U.,T) = 0, 1 < j < h.
n.
such that J J Therefore if n=sup(nl, ... ,n ), tn.T=O, and h n T = Ker «multiplication by t ): G .... G), and is therefore a co-
exists an integer
OX-modules over
herent sheaf of
Xl.
Therefore the assertion
is true for the coherent subsheaf of 0x~modules A
GO~>GO
assignment:
OX-modules over A
Ox-modules over subset and
B
U
AI
of
T
of
G.
from the category of coherent sheaves of
X
into the category of coherent sheaves of
Y
is exact.
X,
The
if
= f (U, OX) ,
B
is flat over
(Since, for every affine open
B,
A
then
AI
r(u,G )""r(U,G )0B O O B
since the ring
B
is Noetherian.)
Therefore we have the commutative diagram with exact rows:
o .. T
.... G
O .... } .... of sheaves of
....
G/T--> 0
!. . (G~T)A_>
0
Ox-modules over
X.
This yields a commutative
diagram with exact rows: di - l . . . di ~Hl(X,T)_Hl(X,G)~Hl(X,G/T) _~ ... i l d -
••• ~H
.
1
JT" )->H .!
(Y,
1
(Y,F)-'>H
. J(G/T)
1
(Y,
A
di )----» •••
Since the assertion is by the inductive assumption true for by the Five Lemma, to prove the assertion for to prove it for
G/T.
Therefore, replacing
G, G
by
T,
it suffices G/T
if
,
Finitely Generated Ideal
793
I
necessary, we can assume that the endomorphism "multiplication by
t
1
of
"
is injective.
G
But then the exact sequence I.8.1 of Chapter
2 applies,
and yields the short exact sequence:
(*)
0
-+
n H (X,G) Atl-'p
[a~
n H (X,G/tiG)]
lim (precise ti-torsion in [ i>O all integers Hn+I(X,G) ring
A,
Hn(X,G) Since
n > o.
G
n l H + (X,G) )]-> 0,
is proper over
Hn (X,G)
X,
and
are finitely generated modules over the Noetherian and, since and
A
Hn+l(X,G)
tl E I,
are therefore I-adically complete. Hn(X,G)
and
Hn+l(X,G)
are tl-adi-
Therefore
n
H (X,G) Hn+l(X,G)
is I-adically complete, by Lemma 5
a fortiori
cally complete.
and
Since
-+
A
tl
n = H (X, G)
has no infinitely tl-divisible elements.
This
latter observation implies that the third group in the short exact sequence (*) (*)
is zero.
Therefore the short exact sequence
implies that the natural map is an isomorphism: (1)
Hn(X,G)
~ lim Hn(X,G/tliG),
all integers
n> O.
i>O Since the functor: Ox-modules over Y
X
Go~>~
from coherent sheaves of
into coherent sheaves of
is exact, and since (multiplication by
tive, it follows that (multiplication by tive 2
A (F", G ).
t t
l
0y-modules over l
):
): F
G -+ G -+
F
is injec-
is injec-
Therefore the exact sequence (L8.1) of Chapter
again applies, and in the same way that we derived equation
Chapter 8
794
(1), we prove that the natural map is an isomorphism ~
n
i
n
all integers
H (Y,F) ':; lim H (Y,F/tlF),
(2)
i~O
But the coherent sheaf
n > O.
is such that
G/tiG
so that the inductive assumption applies, and since (since the functor: sheaves of
Ox-modules over
0y-modules over
Y
X
Govv>~
from coherent
into coherent sheaves of
is exact), we have that the natural map is
an isomorphism:
Equations (1), (Remark:
(2)
and
(3)
complete the proof.
A proof of the result stated in Example 5 above can
be given which is quite different from the one given above (and perhaps even easier).
This alternative, more fundamental, proof
depends on some theorems of mine that yield yet another new, relevant, spectral sequence about cohomology of completions.
I
will come back to this in a later ms.). Theorem 6.
The hypotheses and notations being as in Theorem 1,
assume in addition that: For each integer
h, there exists a sequence
hl, ... ,h
r
of
integers such that hI':: h, ... , h r ':: h and such that hI hr (2 strong) (t , ... ,t ) is an r-sequence for the left A-module l l c i , all integers i E'l!, and such that
(2~tronq) i
2.
j
For each integer
2. r-I,
the left A-submodule:
ci
closed in Let
i E'l'
n
and every integer j, h .. hI i 1 of tl C + .•. + t . JC J
for the I-adic topology. be any fixed integer.
Then if
is
Finitely Generated Ideal Hn(C*/IC*)
n
the natural map is an isomorphism:
and also for the fixed integer
Let
795
is finitely generated as left (A/I)-module,
then for the fixed integer
Proof:
I
Sl={h : l
n
(hl, ... ,h ) r
there exists a sequence
in hypotheses (2 strong)
and
(2~trong)}.
as
Then by Corollary 1.1
of Chapter 5' we have that the natural map is an isomorphism:
The proof is by induction on applied to the ring hI tl ), and the ideal
where where
By the inductive assumption
A' =A/(the two-sided ideal generated by I' = image of
sided ideal generated by A'),
r.
ti, ... '
I t~
in
A'
(I'
= images of
is the two-
t , ... , tr 2
in
we have that
I
is (the two-sided ideal generated by hl,h J is the two-sided ideal in A generated by
These two equations imply the conclusions of Theorem 6. Remarks:
In connection with hypothesis (2 t ) of s rong Theorem 6, it is easy to see that, if r is any integer and if
1.
(tl, ... ,t r )
with identity (tl, ... ,t r )
A,
is a sequence of and if
r
t1, ... ,t r
0,
elements in any ring
M is any left A-module, and if
is an r-sequence for the left A-module
if the elements
~
commute elementwise
M,
then,
(i.e., if
Chapter 8
796
then: positive integers are any sequence of r nr , ... ,t ) obeys condition (1) of Definition 2 (t such that r l nl nr ) , ... , t (t for the left A-module M, then the sequence nl, ... ,n
If
nl
r
r
l
obeys both conditions of Definition 2 for the left A-module i.e., is an r-sequence for the left A-module tl, ... ,t
M.
(Proof:
M, Since
commute elementwise, we have the unique homomorphism
r
of rings with identity: l
'Z' [T , ... ,Trl +A l
Therefore
M
is a
that maps
T. l
'Z' [T , ... ,Trl-module. l
into Since
we are assuming that condition (1) of Definition 2 holds for nl nr nl nr the sequence (t , .. . ,t ), it follows that ( t l , ... ,t ) r l n r n is an r-sequence for the left A-module is an r-sequence for the replacing
A
if necessary, that the ring
with
iff
'Z'[Tl, ... ,Trl-module
(T
M.
and
'Z' [T , ... ,Trl l
1
l
r , ••• ,Tr )
Therefore T. , l
it suffices to prove the assertion in the case A
is commutative.
But then, by induction on n
M
r,
if we know that
l
,t , •.. ,t ) is an r-sequence for M, then it would follow 2 r nl n2 nr that (t ,t , ... ,t ) is an r-sequence for M. (Since, bel r 2 (t
l
n
cause
(t
l
l
,t , ... ,t ) r 2
is an r-sequence for
M,
we have by n
is an (r-l)-sequence for M/t l M. l n2 nr Whence, by the inductive assumption (t , ••• , tr ) is an (r-l) 2 n Definition 2 that
sequence for
M/t
sequence for
M).
l
But by Definition 2, since the ring A nl n2 nr is commutative, it follows that (t is an r' t2 , ... , t r ) l l
case that the ring n,::: 1,
we have that
M.
Therefore it suffices to verify that, in the A
is commutative, that for each integer is an r-sequence for
And this is readily verified by induction on
n).
M.
Finitely Generated Ideal Notice also that, if
r
797
I
is any integer
>
0
and if
is an r-sequence for the left A-module AtiMC tiM,
1 < i
(which of course is the case if
M,
then if
Ati C tiA,
then of course condition (1) of Definition 2 holds. 2. tl, ... ,t
As noted in Remark 1 above if the elements
in the ring
r
A
commute elementwise, and if say
then condition (2 t ) of Theorem 6 fols rong lows from condition (2) of Theorem 1.
i
C ,
and if, e. g. ,
each integer
i).
is an r-sequence for hl hr then, (t l ,.·· ,t r )
At. c t .A, J
J
is also an r-sequence for
ci
(More precisely, if
,
all integers
However, condition
hl, ... ,hr2.l,
(2~trong)
is of course
a messy condition. Suppose that all the hypotheses of Theorem 6 hold,
3.
except possibly hypotheses (2
strong
) and (2
I
strong
are not assuming hypothesis (2 ') of Theorem 1).
)
•
Then if merely
is an r-sequence for the left A-module integers
i
(Also, we
ci
,
all
(i.e., if hypothesis (2) of Theorem 1 holds),
if the technical condition
and
(TC t ) of Corollary 6.1 below s rong
holds, then the conclusionsof Theorem 6 remain valid.
(The
proof of this is analogous to that of the analogous Remark following the proof of Theorem 1.)
E.g., this is the case if
is an r-sequence for the ring A
is commutative.
sequence in
A,
and if
one can eliminate Corollary 6.1. lary 1.1.
Alternatively, if tl, ••• t
r
A
and if the ring
(t1, ••• ,t r )
is an r-
are in the center of A, then
(TC t ), see Remark 1 following Cor. 6.1. s rong
Let the hypotheses and notations be as in Corol-
Suppose also that
Chapter 8
798
(TCstrong)
For each integer
h .:.1,
there exists a se-
of integers such that hI hr (t , •.. ,t ) and such that the sequence:
quence
l
the ring
A,
and s.t. the left submodule
closed in the A-module li,
A-modules
r
F/\
is an r-sequence in hI /\ h j /\ is tl F + ••• + tj F
for the I-adic topology, all free
1 .::. j .::. r - 1.
(If the elements
tl, ••• ,t
are in the center of A then one can
r
eliminate (TCstrong)' see Remark 1 following the proof of Corollary 6.1). Then for every integer
n E 'l',
the natural map is an iso-
morphism:
and liml [h>O Proof.
Let
H~ (A/Ih , C*)]
'C*
"" 0,
all integers
be as in the Proof of Corollary 1.1.
have observed in Corollary 1.1 that gers
n.
n.
Hn(C*)~Hn(,C*/\)
Then we all inte-
Also, the proof of Corollary 1.1 shows (using
(TCstrong) in lieu of (TC)) that
H~(
h (AI (tllA
h
h
+•.. + trrA)) ,C*) "" Hn ((AI (tllA + •••
all integers
n.
But, by condition (TC t ) and the conclusions of Lemma 1.1.1, s rong the cochain complex
'C*
(2'strong) of Theorem 6.
/\
obeys conditions (2 t ) and s rong Therefore the two conclusions of Theo-
Finitely Generated Ideal rem 6 applied to the cochain complex Remarks:
1.
Suppose that
I
'C*A
(tl, ••• ,t ) r
799
complete
is an r-sequence for
the left Noetherian ring with identity
A,
plete for the I-adic topology where
tlA + ••• + trA.
1=
the proof.
and that
A
is comThen by
the same observation that we have made within the statement of corollary 1.1, it follows that if the ring
A
is commutative,
condition (TCstrong) holds, and therefore we have the conclusions of Corollary 6.1. On the other hand, if all of the hypotheses of Corollary 6.1 hold, except possibly (TC s t rong ), and if an r-sequence for the ring
A,
and if also
(tl, ••• ,t ) r
are
tl, ••• ,t
are in r the center of A, then by the argument in part (2) of the Remark
following Proposition 4, we again have that the conclusions of the Corollary still hold. Corollary 6.2. lary 1.2.
Let the hypotheses and notations be as in Corol-
Then for every integer
n
the natural map is an iso-
morphism:
And for every integer
(Here
"(T l' ... , T r )h"
(Tl, ••• ,T ) r
n
we have that
denotes the h'th power of the ideal
generated by
Tl, ••• ,T
r
in the ring
1(T , ••• ,T l r
»).
The proof of Corollary 6.2 is much the same as that of Corollary 6.1. Remark:
As observed in the (analogous) Remark following Corol-
800
Chapter 8
lary 1.2, we can replace
"7(T , ... ,T r )" l
"A(T , ... ,T r )", l
1J'[Tl, ... ,Trl"
or
by anyone of:
IA[Tl, ... ,Trl"
in the
statement of Corollary 6.2. Corollary 6.3. lary 1.3.
Let the hypotheses and notations be as in Corol-
Then all of the hypotheses, and therefore also the
conclusions, of Corollary 6.2 hold. CorolJary 6.3'. lary 1.3'.
Let the hypotheses and notations be as in Corol-
Assume also that the hypothesis,
Corollary 6.1 holds.
(TCstrong)' of
Then all of the hypotheses, and therefore
also the conclusions, of Corollary 6.1 hold. Of course, Corollaries 6.3 and 6.3' follow immediately from Corollaries 1.3 and 1.3', respectively.
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