Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
591 G. A. Anderson
Surgery with Coefficients I
I
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Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
591 G. A. Anderson
Surgery with Coefficients I
I
Springer-Verlag Berlin. Heidelberq • New York 1977
Author Gerald A. Anderson Department of Mathematics Pennsylvania State University University Park PA 1 6 8 0 2 / U S A
AMS Subject Classifications (1970): 57 B10, 57 C10, 57 D 65 ISBN 3-540-08250-6 Springer-Verlag Berlin • Heidelberg • New York 1SBN 0-387-08250-6 Springer-Verlag New York • Heidelberg • Berlin This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher, the amount of the fee to be determined by agreement with the publisher. © by Springer-Verlag Berlin - Heidelberg t977 Printed in Germany Printing and binding: Beltz Offsetdruck, Hemsbach/Bergstr. 2141/3140-543210
INTRODUCTION
This
set of notes
is d e r i v e d
at the U n i v e r s i t y
of M i c h i g a n
author's
doctoral
thesis.
complete
and
in 1973,
from a seminar and p o r t i o n s
It is i n t e n d e d
self-contained
account
to give
of surgery
given
of the
a reasonably
theory
modulo
a set of primes. The material
first
necessary
definitions exception
of relative Included
theorem
of H i r s e h
but
which
in a ring,
2 contains
Gp/H
differs
theorem.
satisfy
Normal and the
i is m a i n l y w i t h the
colocalization
immersion
the theory
is j u s t i f i e d
including
fibration.
Chapter
no new ideas,
and
of the
the b a c k g r o u n d
of
classification
and H a e f l i g e r - P o e n a r u .
collapse-expansion of spaces
the theory.
localization
The d e f i n i t i o n
and Shaneson,
contain
and contains
is a sketch
Chapter torsion.
chapters
to d e s c r i b e
and n o t a t i o n
spaces.
described
three
Chapter
3 discusses
duality
construction
invariants homotopy
modulo
groups
Whitehead
from the one given
by a W h i t e h e a d - t y p e
Poincare
the
of local
with
by Cappell local
the theory
coefficients
of a local
Spivak
a set of primes
of the
classifying
normal
are space
are computed. Chapter
theorem.
Briefly,
obstruction
4 contains groups
to f i n d i n g
the m a i n
surgery
are c o n s t r u c t e d
a homotopy
obstruction
to m e a s u r e
equivalence
the
(over a ring
and
with given torsion) dimension,
cobordant to a given map.
Below the middle
the technique is due to Milnor and Wallace.
homotopy equivalences over the integers,
~he simply connected
case is essentially done by Kervaire and Milnor, by Browder and Novikov;
Considering
and globalized
the general case is due to Wall.
We
show that the obstruction lies in a Wall group of a localized group ring. Surgery over a field was first considered by Petrie and Passman,
and Miscenko noticed that Wall's groups behaved
nicely away from the prime 2.
More recently,
and Pardon have considered rational surgery case),
Connelly,
(in the non-simple
and the methods of Cappell and Shaneson
rings with a local epimorphism
~
+ R)
general case, with rings of the form
Giest
(which uses
also apply.
The
R~, is due to the author
in his thesis. Chapter 5 gives the geometric definition of surgery groups, and the generalization to manifold n-ads. approach is also briefly discussed.
Finally,
Quinn's
the periodicity
theorem, in the non-simple case, is proved. Chapter 6 describes
the result of changing rings
in surgery groups by means of a long exact sequence. include a Rothenberg-type
sequence, the general
Corollaries
periodicity
isomorphism and determination of the kernel of s
L2k_l(
~)
s
÷ L2k_l(~)
~
finite, by simple linking forms,
generalizing the original odd-dimensional due to Wall and clarified by Connelly.
surgery obstructions
Finally,
five appendicies are included:
torsion notions for n-ads,
the algebraic construction of
Ln(W÷w';R) , the computation of manifolds,
Ln(~;R),
surgery on embedded
and homotopy and homology spheres.
arranged into categories.
Whitehead
Undoubtedly,
The reference has been
some errors and
omissions have occurred in this arrangement,
but I hope the
general drift is helpful to the reader. A number of people have been of greaD help in writing these notes.
I am indebted to my thesis advisor
C.N. Lee for many helpful suggestions and discussions.
I
would also llke to thank Dennis Barden, Allan Edmonds, Steve Ferry, and Steve Wilson, who participated
in the seminar,
Frank Raymond, Jack Mac Laughlin and W. Holstztynski.
Massachusetts
Institute of Technology
TABLE
Chapter
i.
OF C O N T E N T S
Preliminaries
i.i M o d u l e s . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.2 H o m o l o g y and C o h o m o l o g y w i t h T w i s t e d Coefficients ................................. 1.3 A-Sets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4 M i c r o b u n d l e s , Block B u n d l e s and S p h e r i c a l Fibrations ................................... 1.5 The I m m e r s i o n C l a s s i f i c a t i o n T h e o r e m ......... 1.6 I n t e r s e c t i o n Numbers . . . . . . . . . . . . . . . . . . . . . . . . . 1.7 A l g e b r a i c K-Theory . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.8 L o c a l i z a t i o n . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
i
7 ll 14 19 23
Chapter
2.
Whitehead
Torsion
28
Chapter
3.
Poincare
Complexes
39
2 4
3.1 P o i n c a r e D u a l i t y . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 3.2 S p h e r i c a l F i b r a t i o n s and Normal Maps ......... 45 Chapter
Chapter
Chapter
with
54
4
Surgery
Coefficients
4.1 4.2 4.3 4.4 4.5
Surgery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The P r o b l e m of Surgery w i t h C o e f f i c i e n t s ..... Surgery O b s t r u c t i o n Groups ................... The Simply C o n n e c t e d Case . . . . . . . . . . . . . . . . . . . . The Exact Sequence of Surgery ................
54 57 60 74 80
5.
Relative
82
5.1 5.2 5.3 5.4
Handle S u b t r a c t i o n and A p p l i c a t i o n s .......... G e o m e t r i c D e f i n i t i o n of Surgery Groups ....... C l a s s i f y i n g Spaces for S u r g e r y ............... The P e r i o d i c i t y Theorem, Part I ..............
6.
Relations
Surgery
Between
Surgery
I01
Theories
6.1 The Long Exact Sequence of Surgery w i t h Coefficients ................................ 6.2 The R o t h e n b e r g Sequence ..................... 6.3 The P e r i o d i c i t y Theorem, Part II ............ 6.4 Simple L i n k i n g Numbers . . . . . . . . . . . . . . . . . . . . . . Appendix
A.
Torsion
Appendix
B.
Higher
Appendix
C.
L Groups
Appendix
D.
Ambient Surgery and Surgery S u b m a n i f o l d Fixed
82 85 94 96
i01 105 109 Ii0
for n-ads
122
L-Theories
124
of Free
Abelian
Groups Leaving
127 a 129
Appendix
E:
References Symbol
Homotopy
and
Homology
Spheres
.................
135
.................................................
138
Index ...............................................
154
Index ......................................................
156
Chapter
i. P r e l i m i n a r i e s
i.i. Modules. Let
A
be a ring
with involution,
i.e.
(not n e c e s s a r i l y
a map
commutative)
A ÷ A, w r i t t e n
k~
~*, so
that
(a)
(~i+12)* = ll* + ~2'
(b)
(Ii~2)* = ~2'~i*
(c)
~** = ~.
We will u s u a l l y units in
A.
be finitely Then
M
assume
i E A.
A
Unless otherwise generated
inherits
denotes the group of
stated,
and right.
all
Let
a left A-module
M
A-modules
will
be a A-module.
structure
by d e f i n i n g
l.m=m.l*. The dual of
M
with A-module
structure
f~ M*,
If
l ~ A.
by giving case
N
M
and
N=A, M @ A A
sum of copies of so that
M @ N
we may choose k.
If
for some
M
given by N
N
M@A
k.
with
= l*f(m), we define
as above.
M
is p r o j e c t i v e
to be free,
M
if there
is s t a b l [ free i.e. M ~ A k
a stable basis
M ~N
In the
(x @ l)W = x @
is free if it is isomorphic
is free.
is s-free,
M* = HomA(M,A)
(f'~)(m)
structure
is a A-module
A.
by
are A-modules,
a left A-module
A A-module
N
is defined
~*l.
to a direct is a A-module
(s-free)
if
is free for some
(s-basis)
is a basis
The m a i n example of A = Rw
for some
~ng.g,
Rw
will be a group ring,
(usually commutative)
a multiplicative The r i n g
A
ring
R
group w i t h a h o m o m o r p h i s m
with
w:w ~ {±l}.
is d e f i n e d to be the set of all finite
ngg R,
g e w.
The i n v o l u t i o n
i,
sums
is given by
(~ng.g)* = ~w(g)ngg -1
1.2. Homology
and Cohomology
Let
X
a homomorphism.
w i t h Twi.sted Coefficients.
be a finite Let
CW-complex,
A = H~
and
M
~ = ~l(X) and
a A-module.
w:~ ÷ {±i}
Define
~{i(x;M) = HI(C,(X) @,,~.~) }Ii(X;M) = Hi(HomA(c , ( X ) , M ) ) , where
C,(X)
the u n i v e r s a l
is the chain complex of cellular cover
X; C,(X)
and based A-modules. with compact HI(X;A),
If
supports.
X
is not compact,
We write
we use c o h o m o l o g y
Hi(X) , Hi(x)
for
Hi(X;A).
determines Let
an element Z/2H
in
HI(x;~/2H)
act on
H
to be the bundle a s s o c i a t e d ÷ X
in
is a chain complex of free
We can define this a l t e r n a t e l y
E ÷ X.
chains
bundle w i t h fiber
and so a double
non-trlvially to
is a principal x - b u n d l e
associated
as follows:
E
w i t h fiber
Let
~t
cover
and define
and so define M.
w
= ~
H. ~
Ht
Now to be the
~ zt.
Then
Hi(X;M)
= H i ( X ; ~ t)
Hi(x;M)
= Hi(x;~)
where we use bundle If
c
is an n-cell in
en:cq(x) where
(or sheaf) homology
defines
linearly to chains since we
supports.
This defines M
This extends
Cn(X) and, in fact, to infinite
are using compact
If
X, cap product
÷ Cn_q(X) @ A ~ Cn_q(X)
cq(x) ~ HomA(Cq(X),A).
chains in
and cohomology.
is a A-module,
~N:Hq(X) + Hn_q(X) define
~:Hq(X;M)
for
~ E Hn(X).
+ Hn_q(X;M)
by
the composition HomA(Cq(X),M) If
f:X ÷ Y
is a map,
~ cq(x) @ ^ M ÷ C n _ q ( X ) @ ^ M . f#:Wl(X)
~ Wl(Y) , then define
Ki(X;M ) = ker(f,:Hi(X;M ) ÷ Hi(Y;M)) Ki(X;M) The condition suffice
~ coker
wI(X) ~ Wl(Y)
f:X + Y
homolo6~equivalence is an isomorphism.
i.
isn't necessary,
with
over X
and
tFpe if there is a sequence
each
÷ Hi(X;M)). but will
for our purposes. A map
homology
(f*:Hi(y;M)
equivalences
over
R
f#:Wl(X) if
Y
~ Wl(Y)
f,:H,(X;Rw)
is a
+ H,(Y;Rw)
have the same R-homology X = Z0,ZI,...,Z m = Y
R~ Z i ÷ Zi+ I
or
and
Zi+ I ÷ Zi~ for
1.3. A-Sets. Let standard
A
n-simplex~
the face maps A
be the category
~i n.
to the category
similarly. between
n=O,l,..., A A-set
X
of k-simplices associated
We define
between
A-sets
is a A-set, of
X.
then
An ordered
to it a A-set
set of k-simplices
of
D(K)
A-groups,
is a natural
functor
by from
etc., transformation
from A-sets
homeomorphic let
X
is called the set
simpllcial
complex
has
by
D(K)(A k) = the
an inverse
to
De i.e. a functor
K, for
K
spaces
so that
a simpllcial
S(D(K))
complex.
be a A-set and form the disjoint
= ~ ] X ( A n) x A n ' where n=0 and we regard
K
defined
to topological
to
X(A k)
K.
We can also define
this,
generated
the functors. If
S
and morphisms
A n , the
is a contravariant
of sets.
A A-map
with objects
X(A n)
is
To do
union
has the discrete
topology
A n = {(t0,...,tn+l)~ R n + 2 1 0 = t 0 ~ t I ~ . . . ~ tn, 1 = i}.
The maps then defined by
~in: An-i ÷ A n
3i n(t0' .
6in+l:A n+l ÷ A n
and
.'tn) . .= .(to' . .
.'ti'ti' .
,t n)
are and
~in+l(t0 ' .... 'tn+2) = (t0'''''ti .... 'in+2)" Then we let relation
defined
(3in+lxn'an+l) an+l~
An + l
'
by
S(X) = X/~, where
~
is the equivalence
(6i n Xn'an 1 ) ~ (Xn'~ n i an-l)'
~ (Xn'Si i=O,...,n.
n+l a
n+l
)
for
Xn6
X(An),
an_l E
A n-1 ,
S(X) See M i l n o r
is called the geometric
[AI~, Gabriel,
Zisman
realization
of
X.
[A6] for a complete
discussion. A A-set
X
admits an e x t e n s i o n to important
An .
The p r o p e r t y
and we describe now a process
A-set into a h o m o t o p i c a l l y
equivalent
If
X
let
by
A(X,Y)(A k) = the set of A-maps
and
ExI(x) Then
Y
are A-sets,
= A(*,X), Ex~(X)
Exk(x)
and Sanderson
[Bl~.
Let
structed of
KH(
to
BH.
H
If
of p r i n c i p a l
a
(Kan [A9])-
be the A-set defined
X x A k ÷ y. Ex~(X)
This is expounded
Define = lim Exk(x).
KH(X)
denotes
H-bundles
over
and
E
H-bundle
has a free classes
X, then in [B10] there is con-
space
if
A-fibration
so that
complexes
here.
the set of i s o m o r p h s i m
BH
and a natural
[ ,BH], the set of homotopy
define a p r i n c i p a l ~:E ÷ X
A principal
~:E + X, where
X.
fully in Rourke
some d e f i n i t i o n s
be a Kan A-group.
More generally,
A-sets
A(X,Y)
We repeat
a classifying )
Kan A-set
any n o t i o n used for simplicial
is an orbit map
H-actlon.
Kan is
for converting
= Exl(Exk-l(x)),
can be used for A-sets.
X
of being
is Kan and has the same homotopy type as
In general,
over
.~n nAn-1. [ -Bi ) ÷ X
is Kan if any A-map
A
equivalence
classes
of maps
is a Kan A-monold,
then we
to be a A-map of pointed
(a)
w
is a Kan fibration
lifting property
(i.e.
satisfies
with respect
the
to the pair
(An,An-~inAn-l)) '
(b)
-l(,)
(c)
there
= A, is an action of
A
on
E, E × A ~ E,
so that E × A
"~ E
proJ. E
,
X
1[
commutes. Again there is a c l a s s i f y i n g equivalence principal
of
H
BH ÷ BA
A-fibrations
over
if
a submonoid is
BA
H
of
X, and
study bundles. Define
[X,BA].
is a A-group and
A
is a A-monoid
A, then the fiber of the map
Let Hq
H
the A-groups be one of
~:A k × ~ q ÷ A k x
~q.
and A-monoids
TOP,
PL,
or
to be the A-set such that
the set of zero and fiber p r e s e r v i n g
~
classes of
A/H.
We now define
and
and a natural
hA(X) , the set of homotopy
As usual, with
space
This means
commutes with p r o j e c t i o n
DIFF. Hq(A k) =
H-homeomorphisms
olA k × 0 to
needed to
~q.
is the identity
Define
Hq(A k) = the set of zero and block p r e s e r v i n g
Hq
by
H-homeomorphlsms
s:A k × I q ÷ A k × I q subcomplex
(i.e.
q(K x i q) = K × I q
K C Ak). Let
R
be a ring and define
the set of zero and fiber preserving over
R
(i.e.
of pairs
with block preserving Define Hq, Hq, H, H
for all
instead
are A-groups,
q.
~ PL = "PL,
According
1.4. Micr0bund!es~
with structure
let
and relate H = TOP,
Definition. complex. space
and
Gq(R),
Hq
and
Gq(R)
or
~ Gq
= GL(q~R)
and Spherical
(R)
= 0q.
F ibrations.
we defined principal or
geometrically
Hq, or bundles
Gq(R).
In
associated
to
As before,
DIFF. [Bg]).
An H-block bundle over
(I)
are A-monoids.
them to the A-set definitions.
PL
but
We have
[B8], DIFFq
section,
groups
similarly
Gq(R)
DIFF = ~D I F F ,
(R0urke ~ Sanderson
E(~)~K
equivalences
G (R) q
H = ---+ lim H q .
Block Bundles
this section we define these
Gq(R)(A k) =
of fiber preserving.
to Milnor
In the previous bundles
by
homology
Define
H = lim ---~ H q ,
TOP = TOP,
Gq(R)
~:(A k × ~ q , A k x 0) + (A k x ~ q , A k x 0)
~-l(Ak × 0) = A k x 0).
Also,
for each
Let
K, written
K
be a simplicial ~q/K,
is a
so that if
~ eK
is an n-cell,
then there
exists
an
H
(n+q)-ball (2)
E(~)
BcE({)
= k.JB . g~K ~
so that
(B~,~)
~ (In+q,In).
(3)
Int(Bol ) n I n t ( B o 2 ) = Z
(4)
Bol N B o 2
\~/
The trivial b l o c k bundle If
~q/K
If
~q/K
and
~qlL nP/L
The W h i t n e y
sum of
If
~q/K
~
over
A(K)cK
~q
and
isomorphism
so that
fl K = 1 K o
x
nq
× K
is the diagonal.
isomorphism
to be
of
= Be(n)
eq/~
and
T h e o r e m i.
([B9])
neighborhood
of
Thus if tangent of
A(M)
M
b l o c k bundle in
is a H - m a n i f o l d
M~ then
M × M.
N
M,
L.
A
f:E(~) ÷ E(n) for all
~q[o.
and
o a K. ~
if
A maximum
N
a regular M'
we can define the
TM, to be a regular n e i g h b o r h o o d
(see [BII] for the case
There are some d i m e n s i o n a l
K.
is a H-block bundle over
is a H-manifold, of
over
o ~ K, is a chart for
of charts is called an atlas. M
L × E(~q)IG(f)
is identified with
collection
If
f:L ÷ K, then
be block bundles
f(Bo(~))
× E(~).
is d e f i n e d by
is defined
I q ÷ E ( ~ I ~ ) C E(~),
it is a bundle
K
is an H - h o m e o m o r p h i s m and
E(~ql L) = L.JB . q~L °
E(~ × ~) = E(~)
= y}
then
then define the
is a block bundle and f*~q/L,
E(~ q) = K x I q.
is a subcomplex,
is defined by
G(f) = { ( x , y ) e L × Klf<x) Let
A map
L
and
where
the induced bundle,
bundle
LCK
~ × n/K x L, by
~
~ = ~ × nIA(K)
where
is d e f i n e d by
are bloc]< bundles,
product b l o c k bundle,
~ ~
eq/K
over
o I ~ o 2.
BO.
is a block bundle and
the r e s t r i c t i o n
if
considerations
H = TOP.
in this case).
We now show how to associate a principal to an H-block bundle. X = D(K).
We define
Let
~q/K
D(~)
Hq-bUndle
be a block bundle and let
to be the bundle
E + X
E(A k) = {hlh:A k x I q + E(~I~ )
where
is a chart,
¢ K, where hlA k × O:A k × 0 + ~ E(A k) ÷ X(A k) action
sends
h:A k x I q + E(~I~ )
E(A k) × Hq(A k) ÷ E(A k)
(in our notation,
Hq(A k)
self H-isomorphisms
of
Conversely,
then
S(~)
eqI~i~
and
by
~, and the
is the set of block preserving
eqlAk). if
~q
s:K + S(E).
~is(~) = s(~ic)'Fi, ~
Define
to
is defined by composition.
is a principal
w:E + D(K), we define an H-block bundle choose a section
is the identity),
If
~
H q -bundle
S(~)/K.
To do this,
is an n-simplex of
for some unique
K,
F £ Hq(An-l).
E(S(<)) = k-#zql~, where we identify cEK
(eql~)l~i ~
by the isomorphism given by
Fi, ~
and the ordering of vertices. These constructions
give the following:
Theorem 2.
There is a I-I cprrespondence
classes of
Hq-block bundles .0.ver
H q-block bundles over Corollary 1.
between isomorp~is ~
K......and ... principal
D(K).
The functor which associates to
K
of isomorphism classes of H q-block bundles over naturally equivalent to
[K,B~q].
the set K
is
Defi.nition.
(Milnor
[B8]).
diagram
K i E j K, w h e r e
and
x * K
for
i(x)
in
E
An H q - m i c r o b u n d l e i,J
are
H-maps,
t h e r e exist neighborhoods and
an
U
H homeomorphism
over
K
is a
so that
of
x
in
joi = i K K
and
h:V + U × ~q
V
so t h a t
V
U
h
U xNq
commutes. The t a n sent is d e f i n e d
by
the
Theorem
same m a n n e r
following
3.
The
isomorp,hism
(see
to
Spivak
as above.
An
fibration
w:E + K
F
R-homology
has
the
of p r o v i n g
which
0,,f ..... H
equivalent
Definition.
of an H - m a n i f o l d
M, TM,
with
associates
to
q-microbundles
2, we can
K
the
over
set of
....K,, i s
[K,BHq].
[El9] for the
R q-spherical
We d e f i n e
Theorem
theorem.
functor
classes
naturally
microbundle
M + M × M + M,
In the prove
U
fibration
fiber
type
Whitney
case
of
F
R=Z).
over
so that
K Wl(F)
Let
K
be
is a = 0
and
S q.
sum,
induced
usual.
10
bundles,
etc.,
as
of
4.
Theorem
The functor
fiber
hom0topy
over
K
1.5.
The
equivalence
associates
classes
is natura!..!y equiyalent
Immersion
In this DIFF.
which
and assume
the r e a d e r
of immersions. locally
flat
Submanifolds in the TOP and
Let a manifold R(TM,TN)
with
M
set of fibrations
Theorem.
may
definition
is f a m i l a r
the
[K,BGq(R)].
manifolds
We use the m i c r o b u n d l e
K
R q-spherical
to
Classification
section,
of
to
be TOP,
PL, or
of tangent
with elementary
will
always
bundle
properties
be a s s u m e d
to be
PL cases.
be a compact dim N = n.
submanifold
Define
of
A-sets
~n
Imm
and
N
(M,N)
and
by I m m ( M , N ) ( A k) =
the
set of germs
f:A k x U + A k x projection,
R ( T M , T N ) ( A k) =
of immersions N, c o m m u t i n g
where
neighborhood
of
identify
and
f
U M
on
Ak x (U~U'),
the
set of germs
projection, of
M
in
U ~u,
f'
~n
and we
if they
of bundle
agree
monomorphisms
commuting
with
an open n e i g h b o r h o o d so that
A k × TU + A k x U x N
11
is an open in
F:A k x TU ÷ A k x TN,
with
the map given
by
(t,u,u') tEA k,
+
(t,u,nF(t,u,u')),
( u , u ' ) c TU,
where
~:TN ÷ N
is an immersion, is the bundle
projection. Choose
an i m m e r s i o n
f:A k × U ÷ A k × N, M C U C ~
df:A k x TU ÷ A k × TN f(x,u)
= (X,fxU).
d:Imm(M,N)
Lees
case, [F2]
surgery
This defines
= (X,fxU,fxU')
a differential
where
map
following
theorem,
Haefliger
and
due to H i r s c h
Poenaru
in the t o p o l o g i c a l
[B3]
case,
[B4]
in the
in the
PL case and
is an i m p o r t a n t
tool
in
theory.
Immersion
Classification
decomposition homotopy
df(x,u,u')
÷ R(TM,TN). The
smooth
by
n, and define
with
Theorem.
all handles
If
M
of index
has a handle
d
body is a
equivalence. We will
messy
details.
Lemma
i.
Let
give a sketch
k < n.
of the proof,
omitting
Then the maps
¢:Imm(D k × Dm-k,N)
÷ Imm(S k-I
× Dm-k
N)
~:R(T(O k × om-k),TN) ~ R(T(S k-I × om-k),TN) defined
by r e s t r i c t i o n
Proof:
This
lifting
property.
is Just
are f i b r a t i o n s .
a matter
See Lees
of v e r i f y i n g
[F2].
12
the h o m o t o p y
the
Lemma 2. Proof:
The theorem is true for
M=D n.
See [B2] or [B3]. Let
¢ g Imm(S k-I × D m-k)
be the fiber of over
¢
over
@
and
and let
imm@(D k x Dm-k,N)
R¢(T(D k × Dm-k),TN)
fiber of
~
Lemma 3.
d:Imm¢(D k × Dm-k,N) ÷ R¢(T(D k x Dm-k),TN)
the
de.
homotopy equivalence . for
k < n.
Proof:
k, using Lemma 2.
By induction on
is a
Proof of Theorem: The proof is by induction on handles in Suppose
M = M 0 U D k × D m-k, M 0 ~ (D k x D m-k) = Sk-I × D m-k,
and that the theorem is true for flat in
A n, D k x D m-k
neighborhood of and
R n.
f cImm(M0,N)
Since
are flbratlons, is
where
@
Imm~(D k x Dm-k,N) is the image of
We have a commutative diagram Imm@iDk × Dm-k,N)--, R~(i(Dk × om-k),TN)
1
Imm(M0,N )
is locally
and the fiber over
imm(M0,N ) + imm(S k-I x Dm-k N).
Imm(M,N)
M
Thus by Lemma I, Imm(M,N) + Imm(M0,N)
(dfe R(TM0,TN))
(R@(T(D k x Dm-k),TN)),
M 0.
is contained in a coordinate
R(TM,TN) ÷ R(TM0,TN)
the map
M.
* R(TM,TN)
;
, R(TM0,TN)
13
f
under
where the v e r t i c a l maps are fibrations. Since by Lemma 3 and induction, maps are homotopy
equivalences,
1.6.
Numbers.
Intersection Suppose
connected
Nn
finite set of points,
gx
*
x
to
from
,oN
Let at
*.
* v ~ V, *w a W. pv~BPw
*v
to
-i
x
in B
a c c o r d i n g to w h e t h e r or not the loop at
k(V,W) We can define manifolds
=
k(V,W)
if
V
define
x~ VNW, where
~
is
is a path in
W
from
gx
Let
Sx = ±I
preserves
the local
number
and
W
of
V
and
W
by
~ = ~I(N,*). are immersed
sub-
in the same manner.
need to define the h o m o l o g y Is closed
where
For
~ gxgx E ~ , xEV~W
To give an algebraic
define
pv,Pw
*.
Define the i n t e r s e c t i o n
N
Choose paths
Wl(N,*)
and
in a
be a basepoint
*w' m i s s i n g all other intersections.
orientation
are simply
v+w=n.
to be the element V
vV,w w
transversally
to b a s e p o i n t s
a p a t h in
and
intersecting
and choose a local o r i e n t a t i o n from
the middle map is also.
is a m a n i f o l d
submanifolds
the top and b o t t o m
for simplicity.
ui-u2 ¢ ~w
to be
U l ' ~ Hn-V(N),
interpretation
intersection For
p a i r i n ~. We assume
~ Hn(N)
correspond
under Poincare duality.
14
k, we
U l g Hv(N) , u 2 ~ Hw(N) ,
u 2 ' ~ Hn-W(N)
of
to
= ~w, Ul,U 2
T h e o r e m i. Let
f:V v ÷ N~
~:W w ÷ N
be immersions.
Then
x(v~w) = f~[V]-g~[W]. Proof: and
Let
R~S
be r e g u l a r n e i g h b o r h o o d s
T ( R ) E H v (R,R-f(V)),
classes.
Let
T'(R)
of
V,W
T(S)(HW(s~S-g(V))
be the image of
T(R)
in
N,
the Thom under the map
HV(R,R-f(V)) ~ HV(N,N-fl(V)) J-~ HV(N) and
T'(S)
similar.
Then
f,[v]
= f,([R]nT(R)) = [N]NJ*T(R) =
Thus
f,[V]'g,[W] Let
= .
i:N ÷ ( N , N - f ( V ) N g ( W ) ) .
[ N ] x ~ Hn(N~N-x) ix[N] =
[N]nT'(R).
Then
= .
Also
is a local orientation,
~(¢x),[N]x,
where
~f
then
Cx:(N,N-f(V)~g(W))
+ (N,N-x).
x
It is clear that
~xg x = < r * T ( R ) U s * T ( S ) , [ N ] x > where
r:(N,N-x)
+ (N,N-f(V)),
s:(N,N-x)÷(N,N-g(W))
= . Thus
~xgx
= [ = f,EV]-g,Ew].
If define
V vC N
is an immersed
self-lntersection
simply connected
numbers
similarly.
15
submanifold
we can
Note we must have 2v=n.
By general position, of
V
in
N
are transverse
a self-lntersection branches
of
is the transverse
x~ V
number
first.
((-l)Vw(gx)Cx)gx -I, where
exg x
first,
W:~l(N)
in
generated
Z~/! v
of
Z~
a-
(-l)Vw(a)a -I = a -
2 (Whitney Assume
t o ..... W;, ,s,,,O,,,,tha, t , .
Since
Let
P,Q
taking one
the answer will be is the
,,of
N
number
Iv
is the ideal
N~V~W,,
satisfY
takin~
V ' ~W, = v
p(V) = [Sxgx
a~.
Let
x,~¢V~W
-
be as,,, above,,,with
~xgx = -Eygy.
V
to
Then
V',,~,,,transverse
{x~,y}.
be paths t h r o u g h
~xg x = -~ygy,
Since
We can
of the form
(-l)Va *,
Lemma).
Thus there is a map pQ-l.
where
by elements
t.,h,ere is an isotopy
Proof:
point.
homomorphism.
is w e l l - d e f i n e d
v,w ~ 3.
of two
the i n t e r s e c t i o n
+ {±I}
Thus the s e l f - i n t e r s e c t i o n
Theorem
locally
as above,
If we compute
taking the other branch
orientation
i.e.
intersection
be a s e l f - i n t e r s e c t i o n
the i n t e r s e c t i o n
branch a r b i t r a r i l y number
double points,
V.
Let compute
we can assume the s e l f - i n t e r s e c t l o n s
V,W,
the loop
pQ-i
f:D 2 + N
so that
is trivial
dim N > 6, we may assume
16
Joining
f(S I) f
x in
and
y.
N.
is the loop
is an embedding.
W
V
Let
R
be a r e g u l a r
this
to c o n s t r u c t
side
of
W.
For
an i s o t o p y details
or R o u r k e
& Sanderson
Corollary
i.
immersions points , homotopic
(2)
~(V!. = 0~ t h e n
the
with
following
to T h e o r e m
intersect
f:v...v.....+.... N n
I(V~W)
= ft.
so t h a t
is a r e l a t i v e boundary,
will
N.
Use
to the
other
6.6
~,:Ww ÷ N
are
in ,,a,f i n i t e
Then
=..¢.
> 6, is an i m m e r s i o n
we
be useful.
2.
17
with
to. an e m b e d d i n g .
of W h i t n e y ' s
leave
s,et,,o,f
f ......is ... r e g u l a r l y
f'(V)Ng(W)
version
which
in
Theorem
and
tra,nsversally
f:V v ~ N n, 2 v = n
corollary
V
5.12.
fi........is .. r e g u l a r l y . h o m o t o p i c
There manifolds
pulls
[B12], T h e o r e m
f':V~ ÷ N If
which
f(D 2)
[DI~,
~ 3, and
to
of
see M i l n o r
(i) .....S...u p p o s e
which
v,w
neighborhood
to the
Lemma
reader.
The p r o o f
for However,
is s i m i l a r
Corollary
2.
Suppos e
Nn
the i.nclusion, i nducin $ g:(wW,~w)
+ (N,8N)
transversally, Then . f that
and
Let
Proof:
of
M
Then there from
which
to
f:(vV,~v)÷(N,SN),
intersect
simply
c0nnected.
f':(V,~V)
+ (N,~N)
s_~o
be disjoint ................... embeddinss
are regular
f,g
intersections
~ E Wl(M). by paths
by the path
Let
homotopies
to embeddinss
f',g'
so
= x.
Since
x = ±~,
n ~ 6, with
= ¢.
F,G:S k x I ÷ M x I ~(F,G)
hom0topic
f,g:S k + M 2k+l,
x ~ ~Wl(M).
that
~ Wl(N).
v,w ~ 3, V , W , ~ V , ~ W
is r e g u l a r l y
3.
~I(SN)
be immersions
f'(V)~g(W)
Theorem
is a manifold,
Join
PI
f(S k)
and
P2 -I ~ PI"
are additive,
P2" Let
and
g(S k)
We Join F
we can assume
f(S k)
be a regular
to the basepoint to
g(S k)
homotopy
which
deform a small d i s c C
f(S k)
along this path and across
a disc transverse
g(sk).
Let
of
x
is
-I, then reverse
It also follows arbitrary
to
G = g x i.
orientation
g f that we can find regular
self-intersection
number.
18
If the sign
in the disc.
-i homotopies
g with
1.7. Algebraic
K-Theory.
Let
A
be a ring.
which are both useful for
L-theory
Definition.
in geometry and will serve as a model
in surgery. Let
We describe here some functors
K0(A)
A good reference
M
is a projective
isomorphism
class, with relations
define a ring structure (I)
If
A
on
X + ~,
If
X compact,
K-functor.
then
[M]
is its
by
We
[M].[N] = [ M ~ N ] . ideal domain,
then
[A]. the ring of continuous
functions
K0(A) ~ K(X), the topological
The correspondence ~
is given by
to the
g~+ r(~),
EX-module
of continuous
F(~). There is a natural
defined by rank, and
~0(A)
classes of projective
modules
relation
and
[M] + [N] = [ M ~ N ] .
Ko(A)
A = ~X,
sending a vector bundle sections
A-module,
is a principal
K0(A) ~ ~, generated by (2)
[C8].
be the abelian group with generators
[M], where
Examples:
is Milnor
[M] ~ [N] The reduced
if
splitting
to finiteness
by a finite
CW-complex,
~
is the set of isomorphism [M], with the equivalence
M ~ Ar ~ N ~ A
K-functor
obstruction
K0(A) = K0(A) ~
s
K0(Z~) measures
for a CW-complex ~ = ~l(X),
obstruction to finding a boundary
for some r,s.
Wall
X
the
dominated
[C10], and the
for an open manifold
Siebenmann[C9].
19
M,
Let matrices
Lo
over
GL(n,A) A.
be the group of invertible
We regard
lj
GL(n,A) ~* GL(n+I,A)
n×n by
n
linear group. Let (i,j)-th
Eij , i ~ J, denote
the matrix
spot and zeroes elsewhere.
~ A, is called elementary. generated
by elementary
The matrix
The subgroup
matrices
with i in the
is denoted
eij = I + ~Eij,
of
GL(n,A)
E(n,A).
Let
E(A) = ~ J E ( n , h ) . n
Lemma. (Whitehead). Proof: matrix in
We have
E(A) = [GL(A)~GL(A)].
1 1 I -~ -i eij = eikekjeikekj , so every elementary
is a commutator.
Conversely,
if
A,BEGL(n,A),
then
GL(2n,A), 'ABA-IB-Io]
=
0
B-1 Given any matrix
0
BA
X, we can write
[: :1 Ii:x :} and [~
~]
i s in
E(2n,h).
Thus
20
E(A) -- [GL(A),GL(A)].
Define the Whitehead
group of
More categorically, the abellan f:M ÷ M
A
by
Kl(A)
= GL(A)/E(A).
we can define
group with generators
Kl(A) to be
(M,f), M
a free A-module,
a A-Isomorphism, with relations (M,f) = (N,g)
if there
is a A - i s o m o r p h i s m
h:M + N
with
(M,f) + (N,g) = ( M ® N ,
hf = gh
f Og)
(M,f) + (M,g) = (M,fg). See Bass
[B2] or Swan
Definition. M
A free and based
is a free A-module
basis
for
M.
Then
A
Define Examples:
p-group
of rank
elementary If
Z
~
GL(n,A)
is an ordered M
bi~-* bi' , is elementary. let
1
for
SL(A)
be the matrices
and define
SKl(A)
= SL(A)/E(A).
SKl(A). Kl(A)
= KI(A)/{±I} , where
(1)
If
A
(2)
If
A = Zw, ~
k, p
then (3)
and
M + M,
÷ Kl(A)
is
A
{ ± l } C A" = GL(1,A).
or a field,
of rank
SKl(RW) If
Z
= 0
then
SKl(A)
pk-1/p-1 for
w
is a skew field,
is the determinant.
21
then
an elementary
an odd prime,
abelian p-group Rc~,
(M,B), where
B' = {bl',...,bn'}
is commutative,
= A" @
is a pair
B = {bl,...,b n}
with determinant
Kl(A)
A-module
basis
if the map
If GL(A)
and
Another
is preferred
in
[BIi].
SKl(A)
= 0.
abelian is an
_[p+~-l]' ~ ~
as above. then
See
Kl(A)
=
[C1].
^ I[A" ,A" ]
The m a i n a p p l i c a t i o n of K I is to torsion. Let 3 3 C:C n + Cn_ I + . . . + C O be a chain c o m p l e x w i t h C i a free and based
A-module.
T h e n by S p a n i e r so that
Suppose
[AI5], T h e o r e m
36 + 53 = 1 Let
and
is acyclic,
4.2.5,
and
is an i s o m o r p h i s m
determines
torsion
of
C.
in fact
define
of free
is i n d e p e n d e n t
Hi(C)
+ C + C
complexes
sequence
of the above
Then
H
is acyclic.
Lemma
i.
Proof:
T(C)
as above,
above
s-free
Definition. If
simple
H
of
6.
the We can
as in [D20]. sequence
be the long exact
regarded
as a chain
complex.
÷ T(.H).
Theorem
3.2.
modifications,
A chain
cone
complex
is a chain ~
we can do all of the
C
is simpl e
homotopy
A
involution
if
T(U)
KI(A)
We say
T(C) then F
= 0. its
is a
= 0.
has an i n v o l u t i o n on
if
equivalence,
is free and acyclic.
equivalence When
induced
C+,C -,
A-modules.
F:C ÷ C'
mapping
of
called
be an exact
and let
+ T(C")
[D20],
With minor
is free, + 0
sequence,
= T(C')
See M i l n o r
Kl(A),
since
TT
0 ÷ C
of chain
in
Then
the bases
The t o r s i o n
!
Let
Using
~(C)
if
= 0.
6:C i + Ci+ 1
A-modules,
an element
~(C)
exists
C- = ~ C 2 i + i .
(3+6) 2 = 32 + 36 + 63 + 62 = 1. 3+6
there
H,(C)
62 -- 0.
C + --~C2i
3 + 8:C + ÷ C-
C
,, then there
also d e n o t e d
22
, ,
is an
defined
by
(aij)* -- (aji*). Define
the Steinberg
with generators
grou p
St(n,A)
for
n ~ 3
to be the group
x ~ij' I ! i ~ J ! n, ~ C A , and with relations x I x ~ = x X+~ ij iJ iJ ~ ~ [xij, x j£] = xi£,
i ~
[x j, x k£] = I, J ~ k, i @ £. There are natural St(A)
= ~JSt(n,A). n
and let Lemma Proof:
inclusions Define
¢:St(A)
K2(A) = ker(¢:St(A)
2.
K2(A) Milnor
S t ( n , A ) C St(n+l,A); + E(A)
let
X ¢(x j) = eij,
by
÷ E(A)).
~ H2(E(A);Z). [C8], Theorem
5.10.
1.8. Localization. Let
A
be a ring and
C(A) = {X~ AIXW = wX be m u l t i p l i c a t i v e l y Define S-1A, if
to be
A × S
There
closed and contain
modulo
so that
the equivalence
class of
on
S-1A
is a natural
by
of
Let
A
(Xt-ws)u (k,s).
.away ... from
23
S,
(X,s) ~ (~,t) = 0.
Let
Define
X/s + ~/t = Xt+~S/st,
ring homomorphism
S ~ C(A) - 0
1.
the relation
u 6S
structure
its center,
w ~ A}.
the localization
there exists
denote
for every
C(A)
A + S-1A
k/s
a ring
~/s.~/t
= ~/st.
given by k ~ k / 1 .
If where
M
S-IA
is a A-module,
we define
has a left A-module
S-IM = M ~ S - ~ ,
structure
defined
by the map
A÷S-IA. Lena
i.
If
M' + M ÷ M"
is exact~ then
S-IM ' ÷ S-IM + S-IM"
is also exact. Proof:
The proof given in A t i y a h - M a c D o n a l d
3.3, works Examples:
since (I)
ICA
be a prime
multlpllcatively
closed
and we let
the localization
of
at
ai~ A,
ki
If
A ACA
For e x ~ p l e ,
away from ~
ideal.
A
Then
A I = (A-I)-IA,
A-I
is
called
I.
is a subset,
a non-negatlve
localization
Proposition
S c C(A) - 0.
Let
(2)
[AI],
integer}. by
let
S = H(A)
Define
kI kn ={a I ...a n I
the
A A = S-!A.
= Z[ ], Z(2 ) = Z[~,~
...3, Q = ~
where
is the set of all primes. Definition. primes. f:X ÷ Xp
Let
X
be a
A localization so that
f
CW-complex of
X
localizes
and
is a space homology,
~,(x) f*,,H,(Xp)
\ f commutes.
24
2
a set of ~
i.e.
and a map
2
Equivalently, A space a
Y
f
localizes homotopy.
(Sullivan [Gi5], Theorem 2.1).
is said to have local homol0~Y if
H,(Y)
is
H(~)
and
B-module. Let
choose a map n-sphere
kl,k2,.., di:Sn ~ S n
S2
be an enumeration of of degree
k i.
Define the local
to be the infinite telescope
of mapping cylinders.
The inclusion
Mdlk~Md2~J...
S n + Mdl ÷ $2 n
localizes homology. Theorem 1. (Sullivan ~15]). Let 0-cell and no 1-cells (e.g.
X
be a CW-complex with one
~l(X) = 0).
Then
X
has a
localization. Proof:
If
X
is a 2-complex, then
2-spheres, and
X ÷ X2 = VS22
X = VS 2, a wedge of
is a localization.
Inductively assume the theorem is true for complexes of dimension
< n-1.
Let
X (i)
be the i-skeleton; write
X (n) = x(n-1)kJf
c(vsn-1), where
f:VS n-1 ÷ X (n-l)
is the attaching map.
to
f2:VS2 n-! ÷ x2(n-l)
c
and let
denotes cone and We can extend
x2(n) = x2(n-l) ~J
Then we have by the Puppe sequence
25
f c(vs2n-I).
([A25]), an exact ladder
VS n-I ~
x(n-l)_+ x(n)_., VS n ~
i
L
VS~-I -'-~f24n-l)-*
I
L
x(n)--* VS2 ~
Since all spaces on the bottom row except homology, that
x2(n)
must have local homology,
X (n) ÷ X2 (n)
SX (n-l)
is a localization.
s4n-l) X~ (n)
have local
and it follows
Now define
Xp = kJX~ (n), which gives the result. n The following theorem is useful
in studying torsion;
it
follows in the same manner as Theorem i, but by considering only those cells in Theorem 2.
Let
~l(X) ~ ~I(Y).
(Y~X)
not in
X.
be a CW-pair with inclusion
Then there is a pai.r
f:(Y,X) ÷ ((Y,X)R,X) homology,
Y
so that
f
localizes
i.e. H, (Y,X)
\
((Y,X)2,X)
f*~ H, ((Y,X)~,X)
/
H,(Y,X) ® Z2. commutes.
26
inducin 5
and a map
relative
Let
X
be simply-connected
Define the colocalization
away from
P
X + X(p).
X ÷ Xp.
We list some elementary properties:
XP
=
Xp
If
wi(X)
(since then P
a set of primes.
P, X P, to be the fiber of
the map
(a)
Similarly let
and
X (P)
be the fiber of
is finite for all
i, then
X = H Xp). P
(b)
If
is the set of all primes, then
(c)
In general,
wi(X P) = rkwi+l(X)
(P-torsion in
Hi(X)) @ (~p,/~)
of primes not in
P
and
X P = *.
rk
, where
denotes rank.
P'
is the set
Thus
~i(x P) ® ~)= 0
~i(xP) ~ ~ = [(~p,_q/z)~kq+l(X)
and
X(p)
(d)
(xP)(p)
(e)
If
= ,;
w2(X)
(XP)p = ( X ( p ) ) ( P ) ;
is finite, then
is the cofiber of
X P ÷ X.
27
q ~ P.
(Xp) (P) = *.
H,(X,X P) ~ H,(X(p))
(see [Kll]).
Chapter Let
w
a homomorphism; natural
(Rw)"
Definition.
let
R
j:~ + R.
generated
by
Wh(w;R)
H C(Rw)" More generally, homomorphism,
if
w
i.
Let
and
~roup of
w
is a
be the sub<w,lm(J)~R'>.
with coefficients
in
where
is a ring and
and S h a n e s o n [ K 5 ] ,
w:w ÷ {±I}
There H
= GL(I;Rw) 6-+ GL(R~)
A
and
Im(J)NR',
= KI(RW)/H
~ KI(R~).
~:~w
+ A
is a ring
Wh(~).
This has been
though
their definition
from the one given here. The homomorphism
on
by
then we can define
done by C~ppell
group
be a ring with
Th9 Whitehead
is defined
Torsion
be a multiplicative
ring homomorphism
group of
differs
2. Whitehead
w
induces
an involution
Wh(w;R).
Examples:
(i)
Wh(l;Zp)
KI(~ P) ~ ~ p ~ ) S K I ( ~
I m ( J ) N : g ; = -+]I(P),
and (2)
Wh(~;Z)
(3)
If Thus
-- 0 : For
,~ if
P h 3,
-- Wh(~) is
as defined
abelian, w
is
of rank
so
then
28
H -- N •p . in Milnor
I'D20].
Wh(~r;R) ~ ( ( R ~ ) '
an elementary n h 3,
P)
then
abelian
/ H) @ SKl(mr).
p-group,
Wh(W;~p)
= (2~p~) / < ~ , w > , this
Definition. R,
Let
~ = Wl(Y).
p ~ ¢.
is true for all
f:X ÷ Y Define
If P.
be a homology
the torsion
of
to be the torsion of the chain complex where
Mf
is the mapping f
if
~(f;R)
• (f;R)
cylinder
is a simple homo!pgy = 0.
In case
is denoted
Lemmas
~(Mf,Y;R)
(2)
If
f Z g
(3)
If
g:Y + Z
z~R~,
f. over
is an inclusion
then
R
X C Y,
are easy to prove
~(f;R)
(see
R=~):
= T(g;R).
is a homology
T(gf)
equivalence
= T(g) + g,T(f), ÷ Wh(Wl(Z);R)
can be defined
for
f
over
where
is the natural if
map.
H,(Mf,X;R~)
(or s-free). The following
Theorem
C,(Mf,X) ~
= 0.
g,:Wh(nl(Y);R)
is free
over
T(f;R)6 Wh(w;R),
equivalence
properties
(I)
torsion
f,
7.5 - 7.8 for the case
R, then
As before,
of
equivalence
T(Y,X;R).
The following Milnor [D20]
f
n < 2, then
i.
= Wl(X),
Suppos e
X
theorem will be useful
in Chapter
is a finite
CW-complex,
connected
and (i)
Hi(X;Rw)
= 0
for
i ~ r
29
4.
(2)
Then
Hr+I(x;M)
Hr(X;R~)
Furthermore,
=
0
is a f i n i t e l y
we m a y
T(C,(X) ~R~;R)
=
every
R~-module
senerated,
our b a s e s
s-free
M.
Rv-module.
so that
O.
Proof: B i = Im(Bi+l),
choose
for
Let
C i = Ci(X) ~ R ~
H i = Hi(C,).
We h a v e
, Z i = ker(~i) , exact
sequences
0 ÷ Z i ÷ C i + Bi_ I ÷ 0 0 ~ B i ÷ Zi ~ Hi which
gives
the
exact
~ 0
sequence
0 ÷ Z i ÷ C i ~ Zi_ I + 0 since
Hi = 0
for
Since induction.
i < r.
Z 0 = CO,
Thus
C,
standard Let
so that
and
~(B'r+l)
is p r o j e c t i v e homotopic
÷ Z
r
for
if
be the
r
This
denotes
= ~'r+l
inclusion
defines the
÷
o ~r+2
-- 0.
30
by
0
4.2.5.).
and
an e l e m e n t dual
i < r
to
( S p a n i e r [AI5], T h e o r e m
3r+ I = i ~ ' r + I.
H o m (,C r _+ l ,_B r ) ~*, t h e n
is c h a i n
proof i:B
Zi
: . • .+ Cr+ 2 + Cr+ I + Z r
C,' by the
i < r
~'r+l:Cr+l in
homomorphism
÷ Br
Thus so
~'r+l ~'r+l
is a cocycle.
But by
is a coboundary.
Thus
(I),
Hr+l(HOm(C,,Br))
~'r+l = f o ~r+l =
Since
2'
is onto,
r+l So
Br
Z r ~ Br ~
Hr'
Cr ~ Zr~
Zr-i
finitely
projective. H(C,"')
is projective.
and
Cr
is finitely
= 0
Since
generated,
Hr
is
: ...÷ Cr+ 2 + Cr+ I ÷ B r + 0
0 ÷ H
+ 0.
r
since
0 ÷ Z r ÷ Cr_ I ~...÷ C,"'
Br
is contractible.
the sum of the even
to the sum of the odd terms.
Zr-i @ i ~ 0
Thus
Cr+2i ~ "~Cr+2i+l'l
to both sides,
~Cr+2i
-~ H r •
@Cr+2i+l.
is s-free. We may choose = 0
an s-basis
by Lemma 1.7.1.
31
for
H
r
is
Let ~
®c,"'@~:~.
is contractible,
has
C O ÷ 0.
Then
c~ ~ c,"
:
is isomorphic
Br @
be
and so
terms
Hr
C,"
C,"'
C," ~ C,"'
T(C,;R)
Zr, and
and so is chain contractible,
Since
r
of
Hr
c,'
H
summand
Thus
Let
the complex
Thus
r+l"
generated.
zero homology
Adding
for some f:Cr÷B r
fi = i.
is a direct
The complex
Then
fi~'
= 0,
so that
be
The result remains true for a finite CW-pair
(Y,X).
We now give a geometric characterization of torsion over
~.
degree
Let
r ~ ~(P)
r; let
cn(r)
Definition:
and fix a map
~r n :sn-I ÷ S n-I
denote the mapping cone of Let
(Y,X)
of
Cr n, CCr n.
be a finite CW-pair and
suppose Y = X ~.~ so that there exists a map
cn(r) ~-~cn+l(r)
f:C~r n
^ n Cr :(Dn,Sn-l) + (Dn'Sn-l)
+ Y, where
is of degree
(i)
flDnvCsrnISn_ I
(2)
fIS n-I
r, satisfying:
is the attaching map for
is the attaching map for
cn(r), and
(3) f(Dn)cx. We say Y ~
X
is obtained from
X, or
P-expansion,
Y
is obtained from X
~
We write X = Y0,Yi,...,Ym = Y Yi ~ ~p
Y
by elementary P-collapse , X
by elementary
Y. X ~
Y
if there exists a sequence
so that either
Yi ~
Yi+l
or
Yi+l' and we say there is a formal deformation over
from
Lemma i.
X
If
~n(Y,X) ® ~
to
Y.
Y ~
X, then
~i(Y,X) = 0
= O.
32
for
cn+l(r),
i ~ n
and
A deformation over
~
is a sequence of maps
{f0'''''fm )'
fi:Yi ÷ Yi+l
the inclusion if
Yi ~
fi:Yi+l ÷ Yi
the inclusion if
Yi+l'
Y0 = X,
Ym = Y"
If
Z
fi[Z = i, then we say relative to Lemma 2.
Y /~
Proof:
Z
f
(Y,X)
X Q Y
Yi
is a deformation over
and
~p
rel X
be a connected
Inductively assume
Wm(Y,X) @ ~ p
Y ~
of type
= 0,
Wm(Zm,X) @
there exists a map cm(r) + Zm
qW-pair so that the
is a homology equivalence over ~ . Then k k where Z = X U ~ ] C n (r i) u k # C n+l (sl). i=l i=l
Zm = x u c m ( r ) U c e l l s
Zm rel X
so that
~p = 0.
f(~D m+l)CX.
cm+l(r)ccm+2(r)
Zm
W.
Here we let
where
Ct(s), t ~ m.
f:cm+l(r) ÷ Zm
where ~
is a subcomplex of each
Yi+l'
Z.
Let
inclusion
Yi ~
Since
It follows that
extending the map Let
W = Zm u f C m + 2 ( r )
is the natural inclusion. D_k (resp. D+ k)
Clearly
denote the lower
(resp. upper) part of the standard k-disc, and
~ D k = ~D k
~+D k = ~D+ k. Let Then since
W' ~ W'
Em+l = ~+D m + 2 c C m + 2 ( r ) C W , X; so
~
X.
Y /~
Zm ~p
W ~
Thus by induction,
33
and
W' = x u c m ( r ) ~ E m+l.
x~cm+2(r)Uhigher
cells,
Y ~
Since
H,(Y,X;~)
Lemma 3.
Suppose
Wn(Y,X) ® ~ where
k cn+l (si). Z = X U k_7 C n (r i) U ~ i=l i=l = O, we must have
Y = xucn(r),
is a free
k=~.
n h 2,
~w-module
with basis
+ (cn(r) ,sn-I ) $
^ n :(Dn' sn-l) Cr
w = Wl(Y).
extends
Then
[$r n] @ I, Cr n
(Y,X) Proof:
It follows easily that
of fundamental is a free
groups.
~w-module
In E Hn(Dn,Sn-l;Zp) is a lift of
We have that with basis
Hn(Y,X;Zp~)
($rn),(In)
= Hn(Y,X;~ P)
where
Srn:(Dn,Sn-l) ÷ (Y,X)
Sr n.
is an isomorphism
of
Wn(Y,X) ÷ Hn(Y,X) , [@]~+ @,(in),
Zw-modules,
~ Hn(Y,X) (9 ~
The lemma is true for S n-I + X
induces an isomorphism
is a generator and
The Hurewicz map
Hn(Y,X;~)
XCY
n=2
and so
~ ~n(Y,X) ~ ~
m ~n(Y,X) ~
provided the attaching map
is a point. Suppose
(Y,X)
is a finite CW-pair with
a homology
XcY
equivalence over ~ . Then by Lemma 2, we can k k assume Y = X U k_7 cn(ri )U ~J cn+l(si ). Let i=l i=l k YI = X U k.7 cn(ri ). By Lemma 3, Wn(Yi,X) ~ ~ and i=l
34
~n+I(Y,YI) ~ ~
are free
[~l],...,[$k ], and ~i,~ i
[~l],...,[$k ]
The matrix of
~i,~i )
~n+I(Y,YI) ~
~
(Y,X)
÷ ~n(~,X) ~ ~p
w,(Y,X) @ ~
Lemma 4.
@i,¢i.
(Y,X)
Then
A
i-th row, column of
X
rel X.
"elementary" ~w,
where
operations Ri,C i
denote
g ~ w, a ~H(P)
(2)
Ci~+ +-aCig
(3)
R i~* R i + xRj
(4)
Ci~* C i + Cjx
A = CBD
is the identity
A:
R i ~+ -+agRi
can be transformed
Y /~
over
(i)
(1) - (4), then
This matrix is invertible
= 0.
on an invertible matrix
A
(with respect to the
(Y,YI,X).
Consider the following
If
where
coming from the exact
Suppose the matrix of
for some choice of
the
respectively,
is defined to be the matrix of the map
sequence of the triple since
with generators
are the attaching maps.
Definition. maps
~-modules
to
x~ ~p~
B
where
by operations of type C,D
matrices.
35
are elementary
Lemma 5. A
Let
A
be the m a t r i x of
can be t r a n s f o r m e d
type
(i) - (5).
Proof:
(I),
B
Then
Y ~
is o b t a i n e d
from
and the m a t r i x of Suppose
operations
A
of type
homotopy
A
Z
is
so that
to
I
X
Z p~
and the m a t r i x X
rel X, and so
Definition. X
and
there
Y
Let
X
and
(Z,X)
Y p~ Y
is
Z I.
or
so that
y /~
Z
By Lemma 4,
be finite CW-complexes. type over
X = Z 0 , Z I , . . . , Z r = Y, each
finite c o m p l e x and simple h o m o l o g y ~p, Z i ÷ Zi+ I
by
X r~l X.
have the same simple h o m o l o g y
is a sequence
Z
o
there exists
of
Y /~
Then
e oetar
rel
of type
B.
can be t r a n s f o r m e d
(i) - (5).
constructions
by o p e r a t i o n s
(Z,X)
Therefore
0f
X.
(3) or (5), then there exists
rel X
and suppose
to the identity by operations
It follows by elementary
that if
(Y,X)
Zi+ I ÷ Z i.
36
equivalences
Zi over
Then ~p a
if
This gives the geometric characterization of torsion: Theorem 2.
Suppose
(Y,X)
is a finite CW pair with
a homology equivalence over iff
Y @
X
and
Y
Then
If
X
and
Y
are finite CW-c0mplexes, then
hav.e the same simple homology type over
and only if there is a deformation from
Definition. 3N = M + U M over
M+CN, N
~p
T(Y,X;~p) = 0
tel X.
Corollary i. X
~.
XCY
Let ,
M+,M_
between
M c N
(N;M+,M_)
and
to
Then M_
N
Y.
is an h-cobordism
provided the inclusions
are homology equivalences over
is called an
i__ff
be a manifold triad,
closed. M+
X
~p
s-cobordlsm over
37
~
if
~.
T(N,M+;~)
= 0.
Theorem
3.
Let
Mn
be a closed
x £Wh(~iM;~p).
Then there
(N;M,M')
T(N,M;Zp)
Proof:
with
Let
and let maps
x
NI
M x I ~
S I x D n-I ÷ M x I Each row of
~2(NI,M). Ri
Since
represents
exists
an h - c o b o r d i s m
k
by a
k x k
2-handles,
are trivial. A, Ri,
~2(M!).
and M i l n o r [D20], T h e o r e m
ii.I,
Ri
by a trivial
Use these
over
~.
to
embedding. NI
to get
See also
Lemma
~p
Let
N.
This
6.2.1.
38
A,
the a t t a c h i n g M ! = ~+N I (M = ~_NI).
an element
N I = M I x I U (n-2)-handles,
an element
over
matrix
where
represents
in
3-handles
n > 5, and
= x.
be r e p r e s e n t e d
be
manifold,
and
By general
of n-2
> 2,
position
is r e p r e s e n t e d embeddings
to attach
is the desired
h-cobordism
Chapter 3.1.
3. P o i n c a r e
P0.incare Dualit~
Let
X
be a f i n i t e
= ~I(X,*)
, and
c E Cn(X)@~. define
c ~
w:~
:cq(x)
tr:C
If
is i n f i n i t e ,
~
n
are u s i n g
Definition exists
X
and c n
(X)
÷ H
X
n-q
is
acts
the
X
; we
give
Definition image
has
[X]
(X;R~)
of
is the m a p p i n g
on.
e H
n
with
([A2],
chaini
formula
over (X;~
~ ,
R
tr(c) pg.
but
since
holds.
if t h e r e
so t h a t
is an i s o m o r p h i s m .
complex are
over
chain
a basis
complexes
of
cycle
given
X
T(D,;R)
e KI(R~)
cone
c ~
of
.
of
is a c h a i n
the d u a l
torsion
R , then
The
for
since free
C,(X)@ARz R~-modules,
equivalence,
[X]
The
by c h o o s i n g l i f t s
free
of c e l l s
basis.
over in X
R
is d e f i n e d
Wh(~;R)
, where
is a s i m p l e
39
to be D,
Poincare
,
243).
n
Cq(X)
The
same
complex
is a r e p r e s e n t a t i v e Cq(X)
transfer
* ,
Given
trivially
is an i n f i n i t e
:HomA(C,(X),Rz ) ÷ C,(X)SARz c
basepoint
to be c a p p r o d u c t is the
class
HomA(C,(X),R~ )
module
the
(X)
is a P o i n c a r e
is a P o i n c a r e
where
in
of
n
~
supports,
a fundamental
dimension
n-q
tr(c)
compact
[X] (% :Hq(X;Rz)
If
÷ C
with
a homomorphism.
, and
(X)@ ~ ÷ C
X
CW-complex
÷ {+l}
, A = ~
where
we
complexes
complex
over
Theorem
i.
simple
R
if its t o r s i o n
If
Mn
Poincare
Proof:
is a c l o s e d
complex
Our proof
be a f i n i t e the
sheaf
U ~
H,(U;~)
~,(Y;~)
over
a more
CW-complex
and
homology
The
stalks
= H,(Y,Y-y;~)
n
over
~,(Y;~)
"~,(Y;~)
According
M
is a
a n y ring.
result.
a sheaf
groups
then over
general
~
of
is zero.
manifold,
of d i m e n s i o n
gives
of l o c a l
R
Let Y
.
Y Define
by the p r e s h e a f
are g i v e n
to B r e d o n
by
[A2],
pg.
208,
Y there
exists
a spectral
sequence
Ep'q = HP(X;~q(Y;Z~))=~Hq_p(Y;~)
Y if
is c a l l e d ~p(Y;R)
constant M
a homology = 0
with
stalks
is a h o m o l o g y Let
If
Y
for
B = R~
manif©id
p ~ n
and
isomorphic
manifold
over
, ~ = ~I(Y)
is a h o m o l o g y
over
manifold
R
of d i m e n s i o n
~ = ~n(Y;R) to
R .
n
is l o c a l l y
In p a r t i c u l a r ,
R . , and over
~ R
as in S e c t i o n
1.2.
, then
H P ( y ; ~ t) & H P ( Y ; ~ )
E p,n ~ E p,n ~
This
isomorphism
simple
is in f a c t g i v e n
on the c h a i n
level.
Hn_p(Y;'.~) by c a p p r o d u c t
See B r e d o n
40
[A2],
and
is
Corollary
10.2,
W a l l [HI9], T h e o r e m Let i.e.,
A C Wh(~;R)
A* = A
C0rollary homology X
1.
.
be a c o n j u g a t e - c l o s e d
(A
If
is a l s o
Mn
Definition. R
called
complex
A finite
R
R
CW-pair
of d i m e n s i o n
n
and
so t h a t
over
f:M ÷ X T(f;R)
with
(Y,X)
if t h e r e
subgroup,
self-dual.)
is a m a n i f o l d
equivalence , over
is a P o i n c a r e
over
2.1.
~ A
torsion
is a , then
lying
is a P o i n c a r e
is
[Y,X]
in
A
.
pair
e Hn(Y,X;Z)
so t h a t
[Y,X] •
:Hq(Y;R~)
is an i s o m o r p h i s m , complex
over
between
Poincare
Theorem
2.
dimension
R
~ = ~I(Y)
so t h a t
X,Y
and
, and =
be P o i n c a r e
(a)
[X] ~ : K q ( X ; R ~ )
(b)
there
(Y,X;R~)
X
÷ K
split
is a P o i n c a r e
[X]
is of d e g r e e
f:X ÷ Y
exist
n-q
~[Y,X]
complexes
Let n
÷ H
A map 1 if
complexes
a 1-connected
n-q
(X;R~)
short
exact
f,[X]
over
÷ Y =
R
[Y]
of
d e g r e e ' 1 map.
is an i s o m o r p h i s m , sequences
f* 0 ÷ Kq(X;R~)
÷ Hq(X;R~)
÷ Hq(Y;R~)
+ 0
0 ÷ Hq(Y;R~)
f~ ÷ Hq(X;R~)
÷ Kq(X;R~)
÷ 0
41
f:X
Then
and
Proof: For
(a) (b),
this
identity.
also
C,(f)
X
H
of
Y
= K
r
is s u r j e c t i v e
holds
in the
torsion
assume
q = n - r + 1 . (X;R~)
and
dimension , X ÷ X'
X'
X
n > 5 . , and
torsion
Then
X
in
case.
Now
Wh(#;R)
Define
satisfies
the h y p o -
= X
there
~JM
Hq(f;R~)
(on the c h a i n
case,
with
complex
equivalence
where
~M
42
M
C,(f)
over
is a P o i n c a r e
homoloqy o
We h a v e
A
be a P o i n c a r e
a simple
, so that
is i n j e c t i v e ;
~ Kq(X;Rz)
÷ Kr_I(N;Rz)
in the r e l a t i v e
Let
f
[X~q(X;R~)
furthermore,
This
3.
A C
(Mf,X)
with
is true
and
relative
in
is an i s o m o r p h i s m
also
Hn_q(X;R~)
2.1.
[X] (~:Kq(N;R~)
Theorem
of cap product.
f* --~
Hn-q(Y;R~)
f,
, and
Theorem
(f;R~)
l
have
Let r
the n a t u r a l i t y
splittings.
result
and
Remark. and
the
= C,(Mf,X)
thesis
~
Thus
defines
A similar suppose
from
the c o m p o s i t i o n
f, -~ Hq(Y;R~)
Hq(X;R~)
is the
follows
~
complex
level).
= C,(Mf,X
of over
over
is a m a n i f o l d
U ~Y)
f r o m ....D n
obtained
Furthermore,
by addin@
~I(M)
1-handles
÷ ~I(X')
Proof:
Assume
X
has one
0-cell
io
say
T h e n we
k
1-cells
can a s s u m e i'
'
attached
at
4°
~i e ~I(X) there
We h a v e
~ , i = ai 4o - ~o
by
4~
with
-
2
.
X
both
ends
, where
By d u a l i t y ,
n-cell Zn and k k Di n = ~ w ( ~ i) £i n-I - ~i n-I i=l
so t h a t
n
i
is d e f i n e d
exists
d i m X ° _<
is s u r j e c t i v e .
is c o n n e c t e d . and
, and
one
we can
assume
(n - l ) - c e l l s
in-1 l coefficients).
(~
,
!
Define of
X
with
X ,
as
X
~ M , where OSM M = Dnu k 1-handles
X
is the (n - 2 ) - s k e l e t o n o n-i , so t h a t ~4n = E w ( ~ i ) ~ i £i
n-I - 4i
~-coefficients.
If
(X,~X)
theorem
remains
t y p e of
(X',~X)
is a P o i n c a r e true,
with
, where
pair
over
(X,~X) X'
~p
having
= X O ~J M ~M
,
, then
the
the
~p-homology
~X C X O
,
d i m ( X 0 - ~X) ~ n - 2 .
Theorem
4.
Let
dimension homology chain
n
so t h a t
equivalences
equivalent
T(Y,X+;R)
(Y;X+,X_)
=
(-i)
the over
be a P o i n c a r e
inclusions R .
Assume
to a c o m p l e x w i t h n-i
~(Y,X_;R)
X+ C
*
43
triad Y
,
over X_ C
C,(Y,X+)
2 non-zero
@ R
terms.
R Y
of are
is s i m p l y Then
Proof: with
Let
matrix
given
by
We may
M
be an
R~-module
A =
(aii)
Then
C.(Y,X+)
0 ÷ C k ÷ Ck_ 1 ÷ 0 . over
R ,
represents
~
(-i) k-I
(-i) n - k on
8 R~
T(Y,X_;R)
Wh(z;R)
(-I) k-I
sends
T(Y,X+;R)
A
Wh(~;R) to
A *t
= (-i) n - k
equivalence
the m a t r i x
is c h a i n of
Since ,
T(Y,X_;R)*
44
+ M*
(a~i)
of
Wh(~;R)
÷ 0
so the m a t r i x
in
is a h o m o l o g y
in
0 ÷ C* 2"÷ C* n-k+l n-k
A *t =
f*:M*
form
Furthermore,
T(Y,X+;R)
, and
the
X+ C Y
is i n v e r t i b l e .
Dually, C.(Y,X_)
has
a homomorphism
homomorphism
has m a t r i x
8 R
Since
f:M ÷ M
the d u a l
f*(x) (m) = x ( f ( m ) ) *
assume
and
2" the
equivalent
to
represents involution
*
3.2.
If
Spherical
~
is
a
R-spherical
is h o m o l o g y
equivalent
then
the
define
Fibrations
Normal
fibration
over
Thorn s p a c e
and
R
to
of
~
Maps
(i.e.
a sphere) by
T(~)
the
p:E
fiber
÷ X
= C(E)U
,
X
,
P where
C(E) We
is
now
prove
Spivak
[EIg].
Theorem
i.
over , so
.
X
, with
Then
the
spherical.
The
Proof:
Let
of
, so
~X
N
M =
~i(N
- X)
for
i = k - 1
~i(N,No)
~N ° = ÷
.
We is
an
Since
for
i ~ k
an
theorem
pair
over
~
%-spherical
equivalent
unique
up
to
of
fibration
to
Hn+k(T(~),T(~I~X); is
of
S k-I ~)
over is
stable
fiber
P
neighborhood
S n+k-I
Let
~i(N)
= 0
of
a regular
.
the
a Poincare
~
M = N N
~M
of
homology
over
S n+k-I
N o~
.
exists
fiber
be
that
in
there
fibration
equivalence
> 4
E
be
generator
homology
k
of
(X,~X)
n
that
cone
a generalization
Let
dimension
p
the
N
=
o
have
N
is
;
an
isomorphism
for
N
is
o
÷ N
- 1
- X
X
a regular
~N - M is
of
in
D n+k
,
neighborhood
then (n + k ) - m a n i f o l d i
< k - 1
a homotopy
and
and onto
equivalence,
.
!
Let NO
÷ N
t If
:E'
÷ N
be
F
is
the
a fibration fiber
of
equivalent t'
45
, then
to nl(F)
the ~
inclusion ~2(N,No)
=
0
•
Let
~ = Wl(X)
so t h a t
Then
[N,~N] ~ :HP(N,No)
Since
(N,M)
so t h a t
~
(X,~X)
[X,~X]~
isomorphism. [X,~X]
isomorphism, ([N, SN] N
exists
U
covers
~)
P
n
(N,M;~)
is an [N, ZN] ~ U =
÷ HP+k(N,No;~
[X, SX] N
Y
t':E'
÷ N
by a s p e c t r a l
e Hn+k(N,~N;Z)
e H
so t h a t
y £ HP(N;%w)
£ H k ( t ') so t h a t
It f o l l o w s
[X,~X]
U s H k (N,No;~)
for
[N,~N]
is an i s o m o r p h i s m .
÷ Hn_p(N;~
Uu:HP(N;~_z)p
U) K3 y =
of u n i v e r s a l
exists
:HP(N,M;~_z)p
since
exists
÷ Hn+k_p(N,M)
, there
Choose
Then
there
.
Now
,
consider
the
fiber
.
with
U u:HP(~;~p)
sequence
z) is an P [N,~N] ~ (y U
F
Y) =
fibration Then
there
~ HP+k(t'~).
argument
that
F = S k-I
mod
C , where C is the S e r r e c l a s s of a b e l i a n g r o u p s w i t h nI nr exponent Pl "'" Pr ' Pie P . (A p r o o f is g i v e n in Browder
[G5],
homology
Lemma
equivalent
1.4.3. over
for ~p
P = 0 ). to
S k-I
Thus Let
F
is
f:E
÷ X
he
!
the p u l l b a c k Spivak
of
t
fibration;
We h a v e
T(~)
by the denote
(Dn+k,s n+k-l)
c ~n+k
(T(~)'T(~I~X))
÷
and (N/No, The
Zn+k(T({),T(~lSX)) ® %
sends
~ ® 1
X c N
.
This
is the
it by
= N/N °
collapse
inclusion
T(~I~X)
= M/~M
M/~M)
defines
the H u r e w i c z
, and the
map
÷ Hn+k(T(~),T(~ISX);Z ) P
to a g e n e r a t o r .
46
To s h o w
uniqueness,
suppose
El:E 1 ÷ X
satisfy
the
(assume
~X = @
form
the b u n d l e
the m a p
F
The m a p Wall
A
a map
Theorem
- ~2 )
be the
"
by
suspension
3.3,F
trivial
T(~I
points
over
~p
homology
type
In S e c t i o n classifying
for
over
fibration
with
Corollary
4.3.,
localized
space
× X
Stably~
and c o n s i d e r
X + X
is a d u a l i t y
which
over
by
map ~p
induces
each
- ~2 )
is o b t a i n e d
E
so
over
we
E E1
over
~ m
by
~p
~2
constructed
fibrations
on coLet
E ÷ X
in
identifying homologically have
the
same
monoids
for p r i n c i p a l with
fiber
a fibration
Gn(~p%
and
Gn(~p)-bundles,
homology
equivalent
~
Such
these
S n-I , and a c c o r d i n g to S u l l i v a n P f i b r a t i o n s are c l a s s i f i e d by the
(BGn) P ,
is
~p .
B G n ( ~ P)
P fiber
in
and
there
fiber
is fiber and
.
- ~2 )
As
isomorphisms
suspending
and
× X
, i.e.,
in d e g r e e s
Therefore
1.3,
spaces
equivalently S n-I
in .
both
simplicity).
x
the d i a g o n a l
obtained
Then
+ X
x (El - ~2 )) = T(~2) /~ T ( ~ l
~p-Coefficients
fibration
for
over
is c o - r e d u c i b l e
with
E1 - ~2
to
A ÷ T(~2
T ( ~ 1 - ~2 ) + S m
homology
fiber
T(~I)
~2:E2
by
is d e f i n e d
[E21], T(~i
~2 × (El - ~2 )
defined
al ÷
S n+k
so
theorem
,
G n = Gn(~)
47
is e q u i v a l e n t
Thus
to a [GI5]
B G n ( ~ P) ~
(BGn) P
Let
SG
be the s u b m o n o i d
n
equivalences cover of
of degree BG
homotopy
of
1.
groups
of
BSG
defined
n
Then
and stably,
n
G
BSG
BG ~ RP
are
is
n
by h o m o t o p y
the
x BSG
finite
universal
.
Since
(~i(BSG)
~ l i÷m
i > 1 ) ,
BH ÷
H = TOP,
(BG)p.
Theorem Then
Let
2.
"]-[ (BSG) p{p (P)
PL or 0. Gp/H
Let
Gp/H ~
Proof:
denote
SGp/SH
(SGp/SH)
Then there
be the fiber of
x 4 +
@ ~p ~ ~i(G/H)
~i(SGp/SH)
® ~(p)
....
÷ ~rl(BH)
÷
Furthermore,
that
~i(SGp/SH)
~I(SGp/SH)
the s e q u e n c e
0 + ~I(BH)
reduces
(BSH) p.
® ZZp,
ladder
÷ ~i
and it f o l l o w s
BSH ÷
~ z i ( B S H ) Q ~(p).
÷ ~i (BSH)
~i(Gp/H)
map
and
~i(SGp/SH)
We h a v e an e x a c t
is a n a t u r a l
the fiber of this map.
"'" ÷ ~i(SGF/SH)
Thus
gi+k+l(Sk),
k
(BG) p ~- K(2~p,l)×
Let
the
(BSG)p)
÷''"
l
Trl((BG) P) ÷ . . . & ~i(Gp/H)
= ~I(Gp/H)
= 0, and
for
i > 1.
~0(SGp/SH)
to
= Z / 2 Z ÷ Zl((BG)p)
48
= ~
÷ ~0(Gp/H)
÷ 0,
= 0.
and so -i ~
~0 (Gp/H) = ~'+p (since the map
-i).
Therefore
Gp/H ~ ( S G J S H )
Break the fibration composition of
Since
(SGp/SH) zi(G/H)
up into the
(BSH)p ÷ (BSG)p.
The
(BSH) (P)~ the colocalization,
fiber of the second is a fibration
and
sends
× ~p+.
BSH ÷ (BSG) p
BSH ÷ (BSH) p
fiber of the first is
~/2Z ÷ ~
(SG/SH) p & (G/H)p.
and
contain one factor of
~i(BSH)
ZZ if
Thus there is
with fiber
÷ (G/H) p
and the
(BSH) (P)
are finite if
i~4k and
i=4k, the long exact sequence
of the above fibration reduces to 0 + zi(BSH) ~ ~(p) + ~ i ( S G J S H )
i = 4k+l, 0 ÷ ~4k+3((BSH) (P))/(~p/~)
÷ Zi(G/H) @ ~p + 0
4k+2 ÷ ~4k+3(SGp/SH)
~4k+3(G/H )
0 + ~4k((BSH)(P)) since any map necessarily
÷ ~4k(SGJSH)
~i(G/H) @ ~.p ÷ ~i_I(BSH) ® ~(p) 0
is
(i~4k).
~4k+3((BSH) (P)) ~ W4k+3(BSH)
also true for
® ~p ÷ 0
+ ~4k(G/H) ® ~p ÷ ~p/~ ÷ 0,
This clearly implies the result for Since
÷
i=4k+3.
® ~(p)
i=4k+l, ~/~,
4k+2. it is
Finally we have
0 -+ ~4k((BSH) (P)) ÷ W 4 k ( S G / S H ) / ~ . ÷ (~4k(G/H)/~)® which concludes the proof since * See Theorem 4.4.3. 49
~
÷ 0
W4k((BSH)
Note:
(P)) @ Z{(p) ~ Z4k(BSH)
In the c a s e
We n o w
show
how
space
Gp/H
P = ~
to S u l l i v a n . Let
n.
P = all
apply
(X,~X)
An H - n o r m a l
the
primes,
Spivak
to s u r g e r y
is d e f i n e d
Z(p).
Gp/H
fibration
theory,
be a P o i n c a r e map
@
pair
due
over
= BSH
and
to be a d e g r e e
50
classifying
in the
R
× ~'+.
case
of d i m e n s i o n 1 map
¢: (M,~M) with
an
for
some
bundle
÷
(X,~X)
, where
eguivalence
M
is a h o m o l o g y Two
oval
in some
large
equivalence
normal
maps
if t h e r e
M1 n
~M 1 =
M2 =
is an
X
over
R
9,
= #i
B:°~N ÷ ~
b:~ M +
~M
is the n o r m a l
We a s s u m e
~I~M:~M
are n 0 r m a l l y
so t h a t
, with
so t h a t
~N = M I U
The
to
BI~M.:OrM.
First
of
the
X .
3.
(2)
and
let
the
Let
case
~
is d e n o t e d
invariants
NIH(x;R)
over
R
of
and
X
~X =
denote
NIH(x;~)
~ ~
the
over
to an
and
(i) ~
~
in this
Let
iff
Spivak
fibration
homology
equivalence
over
c:sn+k--9
T(T)
to
X
is f i b e r
over
so t h a t Making , we get
P)
over
X
homology
over
NIH(x;~)
~ e Hn+k(T(~;~ H-bundle
is a g e n e r a t o r .
o/
H-bundle
case,
be an
regular
is
Then
(i)
Proof:
classes
set of n o r m a l
consider
Theorem
÷ ~i
1
b.
set of c o b o r d i s m
is c a l l e d
M2 ,
an e q u i v a l e n c e
1
equivalent
÷ ~X
.
~:N ÷ X
~IMi
together
of
, ($2,b2)
is a m a p
of c o v e r i n g s
, where
sphere.
(#l,bl)
~M 2 ,
H-manifold,
of c o v e r i n g s
~
cobordant
class
class
H-bundle
of
M
X
+~
a generator,
h:~÷
~p
The
collapse
C , ( i n + k)
= ~
, where
T ( h ) C : S n+k a normal
map
51
÷ T(~)
,
[X,Gp/H]
denote and
equivalent
~
a fiber
defines
a map
_n+k in+ k ~ H n + k ( b ;~p)
transverse
, where M
M =
(T(h)C)-Ix.
;
b Conversely,
let
~ M
CM:S n+k
÷ T ( ~ M)
fibration
be
over
be a n o r m a l
the c o l l a p s e .
~
generator
(2)
It is e a s y
pondence
with
and
let
Then
~
is a S p i v a k
since
T (b), (C M) , :Hn+ k
sends
map
%X
(sn+k;~)
+ H
(T(~);~)
n+k
to g e n e r a t o r .
the
to see
that
NIH(x;~)
set of h o m o t o p y
is in i-i
classes
of
corres-
lifts
BH I
X "~
,>
(BG)
f
where
f
lifts
g0,g 1
denotes
Then
the
denote
, G:X
E ÷ X fiber
the c l a s s i f y i n g
are h o m o t o p i c
X x I ÷ (BG)p f i = 0,1 . Let
P
if t h e r e
x I ÷ BH
denote of
E ÷ X
the a c t i o n
of the
map
fiber
~p/H on
52
~/ , a n d two
exists
, so t h a t
the p u l l b a c k is
for
GIX
E .
x i = gi'
BH ÷
of
;
a l i f t of
let
(BG)p
T: (Op/H)
Clearly
by
f .
x E ÷ E
NI H ( X ; ~ )
is the
set of h o m o t o p y
Since Define
NIH(X;~p)
F: (Gp/H)
is a h o m o t o p y
must over
~X ~ ~
have
an
equivalent and
to m a p s
, then
~X .
NIH(X;~p) over
~p
If
so t h a t
M
equivalence
is a n o r m a l
, there by
F(y,x)
and
so s e c t i o n s
in o r d e r M
# ~
tel ~ I ~ X
R
map.
~ to an
Then
F
corres-
~ ~
homology
~I~X
, we equivalence
is an
H-bundle classes
maps
f:M ÷ X
is a l w a y s
53
.
H-bundle.
is f i b e r h o m o l o g y
, then we will This
s:X ÷ E
E ÷ X
NIH(X;~p)
assume
set of h o m o t o p y
and
of
.
.
for
~X ÷ X ÷ G p / H
E ÷ X
= T(y,s(x)).
and a normal
iff
of
is a s e c t i o n
X ÷ Gp/H
is a m a n i f o l d over
of s e c t i o n s
Thus we may
NIH(X;~p) < >the
X ÷ Gp/H
f
× X ÷ E
H-manifold
~p~ M ÷
Now we have
~ ~
equivalence
pond bijectively
If
classes
over
X
,
of m a p s
to the b a s e p o i n t .
is a h o m o l o g y
henceforth the case
assume if
that
R = ~ .
Chapter 4.1.
4. S u r s e r y
Coefficients
Surgery.
Let an e m b e d d i n g .
where
f,
Mn
be a c l o s e d
Form
M'
We
embedded
say
M'
sphere
If
is o b t a i n e d
from
M x I
Lemma
1.
M',
the t r a c e
k+l
called
and
If the
trace
where
space.
iff
~f0
a
x Sn-k-l,
if
surgery
on
Rourke
Then N
and
say
M N
to
M',
is o b t a i n e d
[J15]
if
that
there
theory.
for
~:M ~ X ~
54
to
H = PL,
This
trace
is
~T
f, t h e n
be a map,
admits
is n u l l - h o m o t o p i c .
and
See M i l n o r
[B12] if
H = TOP.
by
M
is a s e q u e n c e
is an e m b e d d i n g
defined
Let
manifolds
fl,...,fr.
Sanderson
f:S k x D n - k ÷ M
It f o l l o w s
from
is H h o m e o m o r p h i c
by
of M o r s e
decomposition
x 0.
We
between
defined
essence
surgery
we r e g a r d
(k+l)-handle.
surgeries
Siebenmann
of the
U D k+l f,
angle
by
where
surgery.
so that
f0 = f l S k
any
of the
fl,...,fr
a handlebody
M
is a c o b o r d i s m
H = TOP.
H = DIFF,
Kirby
N
be a c o b o r d i s m
is the
the
from
x D n-k,
__if
of the
This
[DI9] if and
N
d i m N _> 6
of e m b e d d i n s s
Proof:
trace
by a d d i n g
Let
with
the
f:S k x D n - k ÷ M
f(S k x 0).
N = M x I •D f
is c a l l e d
and
straightening
f:S k x D n - k ÷ M x l, t h e n and
H-manifold
= (M-f(Int(S k x Dn-k)))
~ flS k x S n - k - l ,
H = DIFF. the
with
and
N
is
N = M ~-/ D k+l, f0 where
an e x t e n s i o n
X
is
~:N ÷ X
Define of c o m m u t a t i v e
Wk+l(¢)
group
of h o m o t o p y
classes
diagrams Sk
Dk+l
C
M
There
to be the
)X
is a long exact
.
sequence
¢# ... ÷ ~k+l(¢) Equivalently,
Wk+l(¢)
an inclusion.
Clearly
from an element If two cases,
in
M
admits
In the
first
into the
× I)UM',
rglative
definition:
cobordant
if there
Lemma
2.
attachin5 to
M × I
fixed
by
f0
comes
interior N
then we c o n s i d e r
or doing
surgery
on
assume
f:S k × D n-k ~ M
of
Do surgery
M.
is a m a n i f o l d
~M' = 3M × I.
This
as
with is called
and
handles
the boundary,
(M!,~M I)
and
is a m a n i f o l d
N
we need
(M2,~M 2)
the
are
with
~P = ~ M I U 3 M 2.
Any c o b o r d i s m
rei
iff
¢
to the boundary.
following
2
÷...
we replace
an e x t e n s i o n
case,
If we w i s h to change
~N = M I U P k 2 M
where
boundary,
the b o u n d a r y
T h e n the trace
~N = M U ( ~ M surger~
¢
has n o n - e m p t y
is an e m b e d d i n g before.
= ~k+I(X,M),
+ Wk(¢)
Wk+l(¢).
leaving
the boundary.
÷ Wk(M)----+~k(X)
to
of
3M × I
(M,3M)
c a n be r e a l i z e d
followed by
~M × I.
55
attaching
bY handles
Proof:
Let
N
~N = M U P U M ' ,
~Q = BM' (Q,~Q)
and
be a c o b o r d i s m
from
~P = ~ M U ~ M ' .
Define
Q × I
is a c o b o r d i s m
(M,~M)
to
Q = M
from
(M',BM'),
UP; ~M
(M,~M)
then
to
since
B(Q x I) = Q x O U ( B Q
x I)taQ
= M x 0 U(PU3M'
Also,
N
is a c o b o r d i s m
to the
boundary
from
(Q,~Q)
x 1
x I)%JQ
to
x I.
(M',~M')
since
~N = M ~ O P U M '
= QUM'
= qu(aq
By L e m m a
i,
Q x I U
N
x I)UM'.
is t h e d e s i r e d
56
cobordism.
relative
4.2.
The
Problem
of S u r g e r y
Let
be a finite
considered homology
here
type
over
is the
over
following:
R
When does
X
have
the
consider
the
of a m a n i f o l d ?
related
problem:
if
is a map,
i_~s ¢
Mn
is a m a n i f o l d
and
cobordant
to a homology
equivalence
R? simplicity,
find a map
¢':M'
To do this,
we would
~k(¢)
÷ X
Since
bundle
equivalent
!.
¢
S k x D n-k ~ M
is p a r a l l i z a b l e , f0*TM
is a bundle of
M
to saying
Let
is n o r m a l l y
to
~
over
in some
large
that
¢:M n ÷ X cobordant
¢
= 0.
in
and do surgery. with
f0
~f0
extends
be trivial. X
sphere.
be a normal
map,
¢':M'
÷ X
to
¢*~
This map,
trivial.
We can do
so that
is a normal
to a m a p
wish to
~i(¢') ® ~ p
elements
if
must
We thus
with
like to r e p r e s e n t
f:S k x D n-k ~ M, then
normal
R = Zp.
f0:S k ÷ M~ be an e m b e d d i n g
S k x D n-k
if there
assume
cobordant
by e m b e d d i n g s Let
Lemma
The m a i n p r o b l e m
on this problem,
For
this
CW-complex.
To get a t o e - h o l d following ¢:M ~ X
X
with Coefficients.
is the
is
as in Section
n ~ 5. with
Then ¢'
[n/2]-connected.
The proof
over
R
will
be given
below.
By C o r o l l a r y
3.1.1,
of a m a n i f o l d ,
then
if X
X must
57
has the h o m o l o g y be a Poincare
type
complex
3.2.
over
R.
degree
Furthermore,
1.
Our p r o b l e m
i)
When
is the
2)
When
is
¢:M ÷ X
Question
1 is best
lifting
X ~
of these
notes.
Wall [HI9]
let
subcomplexes
of
there
a handle ¢i:Ni
Assume
X
~ Xi
Cr+l:Nr+l
cobordant
have
to a h o m o l o g y
the o b s t r u c t i o n
2 will
the
Ni,
NO = M
Ni_ I
Assume
and a h o m o t o p y
We construct
i ~ r.
cells
N
the rest
of
of
X-M
by i n d u c t i o n
I, o b t a i n e d
x
to
Following
be a sequence
one at a time.
to
occupy
is an inclusion.
by a t t a c h i n g
manifolds
for
must
an H - b u n d l e ?
XI,X2,...,X m
formed
of index
X
Question
¢
exist
¢
to two questions:
by a n a l y z i n g
BH.
M = X0,
of d i m e n s i o n that
to
i:
of
that
R?
answered
(BG)p
of Lemma
fibration normally
over
shows
is now r e d u c e d
Spivak
equivalence
Proof
a calculation
by a d d i n g
equivalence
and
r+l
÷ Xr+ I. Suppose
8N r = M U M r ,
determines
Xr+ I - X r
the d i m e n s i o n
an element
of that
Since
N
handles
of index
_
handles
of index
> (n+l-k)
is i-connected, a ' g wi(¢r )
and
a m ~i(X,Xr),
cell
where
i
is
cell. is formed
r
The
Cr = CrlMr"
so
correspond
from
it is formed > k+l
M x I from
Mr
> i+l.
~i(¢r ) ~ wi(X,Xr). to
~, and let
58
by a t t a c h i n g x
I
Thus Let
by a t t a c h i n g (Nr,M r )
CJ
S i-I
Di
I g0 ,X
M
be a representative Since X
so that
f0'
Classification
i-1 < [n/2],
equivalence.
f
Continuing
the k-skeleton
of
Therefore
(Nm,M m)
~m:Mm ~ X
is k-connected.
are actually
Corollary (Y,X)
i.
is s-trivial.
is a finite
is normally (a)
if
if
f
an
is an embedding. + Xr+l, we get
(X,X m)
a homotopy X m = M U X (k),
is k-connected.
and it follows
that
It is easy to see that
~
and
cobordant. + (Y,X)
CW-pair,
X a finite
to
n = 2k,
~'I~M' (b)
flS i-I x 0 = f0'
#:(Mn,~M)
cobordant
This
T(S i-1 x D n-i+l) ~ TM.
inductively,
normally
Let
is contractible,
so that
is k-connected
over
back by
this defines
~r+l:Nr+l
X, so
Di
~
Theorem,
we may assume
to get
is a bundle Pulling
But
f0*TM
f:S i-1 x D n-i+l + M
Do surgery on
~m
trivial.
is s-trivial. Thus
there
a stable bundle m o n o m o r p h i s m
immersion
X (k)
is stably
is trivial.
By the Immersion
Since
Is a normal map,
J'g0 *~
J'g0* ~
defines
~
T M ~ ~*~
f0*TM~
so
of ~'
be a normal map, where CW-complex.
~':(M',3M') ~'IM'
+ (Y,X)
is k-connected
Then
where and
is (k-l)-connected.
n = 2k+l,
~'IM'
k-connected. 59
and
~'I~M'
are
4.3.
S ursery O b s t r u c t i o n We describe
L-theory Let
A
Groups.
here the functors
w h i c h provide
us with surgery o b s t r u c t i o n
be a ring w i t h i n v o l u t i o n
ideal generated
by
Definition.
(-l)k-Hermitian
(G,k,~) X:G
×
A
where
G
A
Ak
in
direct
~:G ~ A/i k ):G ÷ A
form over
be the
are maps
A
is a triple
A-module, so that
k(x,
(b)
k(y,x)
= (-!)kk(x,y) *
(c)
k(X,X)
: ~(x) + (-l)k~(x) *
(d)
k(x,y)
= ~(x+y)
(e)
~(xa)
(f)
Ak:G ÷ G*,
is a k - h o m o m o r p h i s m
-~(x)-~(y)
: a*u(x)a.
of the form
Ak(x)(y)
(G,k,~)
= k(x,y)
is an isomorphism.
is defined
to be the t o r s i o n
e,f
~(e)
KI(A).
~ I, then
G
has a basis
(G,k,~)
sum of standard Let
be a self-dual
subgroup.
Definition.
(G,k,~)
a free and based
A
is called a kernel.
form is one with torsion
Let
~ ~(f) = 0,
is called a standard plane.
planes
ACKI(A)
with
(-l)k-A-Hermitian
HCG
Ik
groups.
xeA
(a)
In case k(e,f)
and let
is a free and based
and
The t o r s i o n of
*
x + (-l)k+Ix *,
G
of algebraic
in
A.
be a (-I) k A - H e r m i t i a n
submodule.
Then
60
H
An
form and
is called a
subkernel
of
(G,I,~)
preferred basis for I(H x H) = 0, by
I
if the basis of
G, making
G/H
H
based, and
~(H) = 0, and the map
G/H ÷ H*
is an isomorphism with torsion in
Lemma i.
(G,k,~)
extends to a
defined
A, an A-isomorphism.
is a kernel iff there is a subkernel of
(G,I,~). Proof:
If
(G,I,~)
is a kernel, then
el,...,en,fl,...,f n 1(ei,f j) = 61j ,
so that
Conversely, Then, as
G/}I ÷ H*
basis for
el,...,e n. let
el,...,e n
= 0.
Then
Then is a basis for
be the
is a subkernel. H.
we get a H*.
Let
of this basis in
1(ei,f j ' ) = (-i )k~ij , and G.
H
be the basis for
is a A-isomorphism,
be representatives
Let H
G/H, using the dual basis for
fl',...,fn'
has a basis
u(ei) = ~(fi ) = O,
1(ei,e j) = X(fi,fj)
submodule generated by
G
G.
el'''''en'fl
'''''fn'
Define
fi = (-1)kfi ' + (-l)k-l(ei~i
+
~ e.1(fj',fi')) i<J j
where
~i E ~( f'i ). Then shows
G
is a basis for
G
and
is a kernel.
Corol!ary i. a subkernel of H + H'
el,...,en,fl,...,f n
Let
H
be a subkernel of
(G',I',~').
(G,k,~)
and
H'
Then an A-isomorphism
extends to an A-isomorphism
61
(G,X,p) ~ (G',k' , p')
J
Definition.
Define
(-l)kA-Hermitian direct
LA2k(A)
forms over
A, with addition defined by
sum, modulo the equivalence relation
there exist kernels Lemma 2. Proof:
to be the semi-group of
LA2k(A)
K,K'
so that
if
G ~ G'
G ~ K ~ G' ~ K'
is an abe lian sroup.
All we need show is that
kernel.
Let
ei',ei"
the corresponding
el,...,e n
(G,~,U) ~
be the basis of elements in
(G,-k,-~)
G.
is a
Denote by
G ~ G,
e i' : e i + O,
el" = 0 + e i • Let
HCG
~ G
be generated by
~(e i' + ei",e j' + ej") = O, Furthermore,
the map
G ~ G/H ÷ H*
ei'~-~ ~(ei' , and so has matrix k(ei,ej). H
(aij)
Then
u(e i' + el") = O.
is given by
)
where
But by hypothesis
e i' + ei".
aij = ~(ei',e j' + ej") =
this matrix is in
A.
Thus
is a subkernel.
The group
LA2kCA)
is called the
To define odd dimensional
(2k)-th Wall sroup of
surgery groups, let
A.
Kn
denote the standard kernel with basis el,...,en,fl,...,fn,
~(e i) = u(fi ) = 0,
~(el,e j) : ~(fi,fj) = 0, Let
Uk(n,A)
~(ei'fJ) : 6iJ = (-1)k~(fj'ei)"
denote the group of isometries of
the group of A-automorphisms
Kn ÷ K n
62
preserving
Kn, i.e., k
and
~.
There is a map matrix; let
Uk(n,A) ÷ KI(A)
UkA(n,A)
Let
sending an isometry to its
denote the inverse image of
EUkA(u,A)
be the subgroup of
ACKl(A).
UkA(n,A)
generated by (a)
isometries which fix the subkernels generated by
{el,...,e n}
and
{fl,...,fn}, and induce
automorphisms with matrices in (b)
isometries which fix
(c)
the isometry
an
Then
EUkA(u,A)
el,...,e n.
defined by
en(fl ) = (-l)kel '
A.
an(e I ) = fl'
~n(ei ) = el'
~n(fi ) = fi' i > i.
can be regarded as the group of matrices
generated by matrices of the form
(a)
IP°l
(c)
the
Embed way; then
0
p,-1
'
PEA'CGL(n,A),
0
t
(-i) k
0
matrix
UkA(n,A)
the inverse image of
0
in
UkA(n+I,A)
EUkA(n,A)C EUkA(n+I,A).
63
in the obvious
A,
Define
UkA(A) = lim UkA(n,A),
The (2k+l)-th Wall 5roup 0f
A
EUkA(A) = lim EUkA(n,A). is defined by
UkA(A) LA2k+l(A) =
/EUkA(A).
We will show in Corollary 5.2.1 that abelian group for
A = ZpW.
LA2k+l(A)
is an
It is in fact abellan for all
A, as is shown algebraically in Wall [H19]. Consider the following surgery hypothesis: (M,~M)
be a manifold pair with
dim M = m > 5,
a connected Poincare pair over ¢:(M,SM) ÷ (X,~X) ACWh(w;~), (X,~X)
of dimension
a normal map.
Let
(X,~X) n,
Suppose that
w = ~l(X), is self-dual and the torsion of
is in
A;
assume
equivalence over
~
¢I~M:~M + ~X
with torsion in
is a homology A, under the map
Wh(~i(~X);Z P) ~ Wh(~I(X);Ze). Theorem I.
There is defined an element
~(~) E L n A ( ~ w ) ,
which depends only on the normal cobordism class of so that
0(¢) = 0
if and only if
¢
¢,
is normallY cobordant
relative to the boundary to a homolosy equivalence over with torsion in Proof: ¢ for
Case 1.
n=2k.
is k-connected. i < k
Ki(M;~w) i 9 k.
and = 0
A. By Lemma 4.2.1, we may assume
By the Hurewicz theorem,
Kk(M) a ~k+l(¢). for
i > k, and so
By Theorem 2.1,
By duality Ki(M;Zp~) = 0
G = Kk(M;~)
64
Ki(M) = 0
for
a Wk+l(¢) @ ~
is s-free.
Then
G* ~ K k ( M ; ~ )
an i s o m o r p h i s m following
G ÷ G*
Theorem
k:G x G ÷ Zp~, numbers,
as every
immersed
k-sphere.
then we replace G
is r e p l a c e d
class
of
by adding
¢,
G ~
¢':M'
K1,
handles
f
show that
¢:N ÷ X
function
class
we may
assume
sending
x
By C o r o l l a r y
to
= 0,
4.2.1,
and c h a n g i n g
exact
sequence
of
(N,~N)
0 ÷ Kk+l(N,~N;~) we can assume
e
and
Thus
is free.
Let = 1.
in
M,
is the
1 x S k. G
@(M')
Routine form.
LA2k(~).
cobordism
class
between
¢
and
~:N ÷ I
be an
T h e n the map
(X x I;X x 0,X × i)
is a degree
we can assume Kk(M')
of
cobordism
with
(¢(x),¢(x))
where
only on the
x I U M'.
÷
in
M # ( S k x sk),
(G,k,~)
~N = M U ~ M
fixed
where
of
be a normal
¢:(N;M,M')
by an
is a ( - 1 ) k A - H e r m i t i a n
depends
~(M)
by i n t e r s e c t i o n
(k-1)-sphere
sum
is the
(G,X,U)
c(¢)
defines
by s e l f - i n t e r s e c t i o n s .
K 1 = <e,f~,
to be the class
÷ X, with
Urysohn
connected
gives
by the remarks
is r e p r e s e n t e d
on a trivial
trivial
let
G
duality
is given
surgery
and
o(¢)
1.6.1
u:G ~ 2P~I k
by the
by
A
Define
M
To show of
of
in
isomorphism
by T h e o r e m
Sk x 1
calculations Define
This
element
If we do
Poincare
with m a t r i x
3.1.2.
which
and
Kk(¢)
by adding reduces
map.
= 0, k e e p i n g
a kernel.
The
~ Kk(N;~)
long
+ 0,
free and the t o r s i o n
G5
M
to
~ Kk(BN;~)
all m o d u l e s
i normal
of the
complex
above lies in
Kk(M;~w)
- Kk(M';~w)
show that that
spheres.
,
~aD
k
p'
intersections
of
ax
with t o r s i o n @
and
in
¢
with torsion
say
on this e m b e d d i n g and
N
X(x,x')
ax'.([B12]) Thus
~
Kk(M;~)
p
= k(ax,ax,)
Similarly
is a c o b o r d i s m equivalence
: 0, we have
~(~x)
= 0,
in
= 0, and
invariant. over ~(@) = 0
equivalence
if
~(@) = 0, then
Zw ÷ ~ w
Since
Kk(M; ~ ) N(e m) : 0,
by Corollary
1.6.1.
is InJective.)
over
as in Lemma 4.2.1.
Let
N = M ~ D k+l = M' u
66
D k.
is a em (This
Do surgery
M'
be the result
the trace of the surgery. We have
restricted
transversally
to a h o m o l o g y
by an embedding
uses the fact that
so that
intersect
e l , . . . , e m , f l , . . . , f m.
is r e p r e s e n t e d
is a
A.
Conversely, kernel,
ax', then p'
cobordant
in
D k) ÷ N
is a homology
A, then
is n o r m a l l y
and so there
and paths with ends r e p r e s e n t i n g
is a kernel. Since if
so for
ax.
and
set of circles
Using
by a sum of maps of
Wk(N),
represents p
shows
has a basis
of spheres,
o:(S k+l - U I n t
since we can assume
Kk(aN)
in
represents
If
if
0
Duality
Kk(aN)
is r e p r e s e n t e d
represents
, and so we need only
~ Kk(N;~w)*.
throughout,
This sum is
Kk(aN;~w)
is a subkernel.
~ Kk(N;~w)
ax
framed immersion
a finite
LA2k(~W)
by framed immersions
X~Kk+l(N,aN)
so
in
coefficients
represented
to
Now, the form
Kk+l(N, aN;ZpW)
Kk+l(N,aN;~w)
A = ~w
A.
The map
j,:Kk(M;ZpW) given by
÷ Kk(N,M';~)
j,(x) = l(em,X).
l(em,f m) = 1.
0
Kk+l (M')
Kk+I(N)
o
o ~
/\/\
Kk(N)
Kk_l (M')
Kk(N,~N)
0
\/\ 0
Kk(N,SN)= Kk_I(M') = 0.
0
Furthermore,
N = M U D k+l, and the map
sends the generator to
represents the attaching map.
Thus
~
em, since is inJective
Kk+l(N) = Kk+l(M') = 0. A basis for
el'''''em'fl .... 'fm-l' these elements.
Inductively, Zp.
since
em, and so
is given by
ker(J,)
is generated by
Kk÷l(N,M ) ÷ Kk+l(N,~N)
sends
Kk(M') ~ <el,...,em_l,fl,...,fm_l>.
we can do surgery to get a homology equivalence
Also, we chose bases so that
took care that Case 2.
Kk+l(N,~N)
Also, the map
the generator to
that
since
(~w-coefficients)
Kk(N,M' )
Kk(M') ~
8:Kk+l(N,M) ÷ Kk(M)
and so
is surJective,
/\
Kk+l(N,M) ~ Zp~, since
over
J,
Kk(M)
Kk+I(N,~N)
J\/ we see that
Thus
is easily seen to be
Looking at the exact braid
K•N•
°/'
em
~ Zp~
~(C,(~'))~ A.
n = 2k+l.
embeddings representing
Let
¢
is k-connected,
gi:S k × D k+l + M
a set of generators of
67
and
Thus we have the result.
Again assume
Kk(M) ~ ~k+l(~).
~(C,($))~ A
so
be disjoint Wk+l(~).
Let
U = Ugi(sk
x Dk+l),
M 0 = M - Int U.
By Theorem 3.1.3,
we can assume there is a Poincare pair over torsion in ¢
A, (X0,Sn-1) , so that
by a homotopy,
triads
with
X = X O u D n.
we can assume
Changing
is a degree 1 map of
(M;M0,U) ÷ (X;X0,Dn). The modules
bases given by
Kk+l(U,SU;~pW)
and
Kk(U;~pW)
e i = (gi(1 x Dk+l), gi(1 × sk))
fi = gi (Sk × 1).
have
and
Then in the sequence
0 ÷ Kk+l(U,~U;*pW ) ÷ Kk(~U;~p~ ) ÷ Kk(U;~p~) ÷ 0 these
combine to g i v e a b a s i s
In fact,
Kk(~U;~w)
a subkernei.
{ e i , f i i}
is a kernel
and
We h a v e t h e d i a g r a m
Kk+l (M)
Kk+I(U,~U;~w)
is
Kk(M0 )f'---''~ 0
Kk(~U)
Kk(M)
/'\ / \
0k....w~ Kk+I(M,U)
= Kk+I(M0,~U)~__.~
By theorem 2.1,
Kk+I(M0,~U)
can assume it is actually is a subkernel. Then the map
Let
~:Kk(~U)
~
in
As above,
be a basis for
÷ Kk+I(M0,~U) , ÷ Kk(~U)
the matrix of
be the class of
Kk(U)~.._._~
a
0.
is s-free and s-based.
free.
{el*}
Kk+I(U,SU)
to an isometry Furthermore
Kk(~U;ZpW).
(~pW c o e f f l i c i e n t s )
0 f-''~ Kk+I(M,M 0) = Kk+I(U,~U) ~ ' ~
\/ /\
for
is in
LA2k+l(~W).
68
Kk+I(M0,~U) Kk+I(M0,~U).
ei~-* el* , extends
by Corollary A.
We
Define
4.3.1. o(¢)
to
To show
c
is a c o b o r d i s m
that surgery on the e m b e d d i n g and
gl
g!(! x sk),and replaces
unaffected
by surgeries
a
with
then we can assume
and so the pairs
(N,~+N),
(N,3_N)
Theorem
2.1, we can assume
based, w i t h g e n e r a t o r s Let
Then
s-cobordism
~
homology o(¢) = 0.
where
a0
equivalence Then
~_N'
class of
over
if ~.p
form
or
If
corresponding
to
(-i)k
gi
replaces
= (-l)kc -I, we may write
~_N.
and so
¢
to
N"
~+N.
is an
Thus, c(¢)
over
[o 1 R*-I
to a
A.
Now suppose
a = a0-a I ...a m,
and
ai
is either of
'
(-1) k
'01
' the surgery on the
a
~p,
depends
is cobordant
Write
(stably)
am =
By
is free and
with t o r s i o n
0
the
>k.
¢.
ag EUkA(r,~w).
is of the form
Thus
which generate
N = N' t9 N", where
c(@) = 0
is a
are k-connected.
need be considered,
Clearly
is
is (k+l)-connected,
Kk+I(N,8+N;Ep~)
from
only on the c o b o r d i s m
~
~:N ÷ X
given by handles a t t a c h e d
Kk+I(N,~+N;~).
only k-handles
If
c(¢)
of handles of index
N' = ~+N x I k A k - h a n d l e s
over
gl(S k x i)
ae n. Thus
on k-spheres.
has a handle d e c o m p o s i t i o n
note first
interchanges
normal cobordism,
N
invariant,
with
a = a 0 ...
68
ao.
But as
am_ I.
fl Q1
m
If
a matrix over
lj thonorsome
Zw.
Replacing
h:S k × D k+l ÷ S k x Int D k+l
replaces
a
with
with
is
gi o h, where
is an embedding of degree
p,
01 lq 0I
-I p
Io As
gi
pQ
I
pI
m lq
?I
is a simple isometry, we can assume pI
~m = [i
~]
where
Q
is a matrix over
~
with
Q = QO + (-l)k+iQo*" Let
H
be a regular homotopy of
U g i : W S k x D k+! ÷ M
to disjoint embeddings, where the intersection matrix of the
immersion
H
matrix given by
1.6.3.
[~-~0).
The spheres
bound disks in
nd el Intersectlon
is given by
M
This can be done similar to Theorem
gi(l x S k)
are unchanged, as they
but the sphere
by the other end of the homotopy.
gi(S k x i)
is replaced
This replaces
70
a
by
~.
= s0
am_ I.
. . .
Thus by finitely many surgeries we can assume
m =
But
R
has image in
A, so by a change of
R,_ 1 •
basis, we can assume assume
m
is of the form
m(el) = (-l)kfi ,
fi*
for
By surgeries on the
gi' we can
±e ~ . . . ~ a, i.e.,
a(f i) = e i.
The bases of a basis
a=l.
Kk+I(M0,~U)
Kk(M0).
and
Kk(~U)
determine
Thus after all surgeries, the
maps in the diagram above become
(Zp~ coefficients):
Kk(~U) ÷ Kk(M0):ei ~-+ fi*,fi ~-+ 0, Kk(BU) ÷ Kk(U):fi~-* fi,ei w-* 0, Kk+I(M,U) ÷ Kk(~U):ei*~-~ (-1)kfl, Kk+I(M,U) ÷ Kk(U):ei*~-* (-l)kfi ,
Thus the map torsion in
Kk+I(M,U) ÷ Kk(U) A, and so
is an isomorphism with
Kk+i(M;Zp~)
• (C,(¢);Zp~) ~ A.
71
= Kk(M;ZpW) = 0, with
T h e o r e m 2.
(Realization
compact manifold, Then there
n ~ 6; let
is a m a n i f o l d
$:(X;~+X,~_X) ~I~_X
X
Zp
Proof:
Suppose form
homotopy
(G,l,~)
~Is+x
Then
fi'
el,...,e n.
Let
into disjoint Fi
by a
discs,
be a regular l(Fi,F j) = P i j l ( e i , e j )
P i j , P i ~ H(P). attached
by the maps
we can extend
to a normal map
¢:(X;8+X,~_X)
+
to
(G,I,U),
~
x, where
K
trivial
Thus
Thus
with t o r s i o n
in
we can again extend
Kk(X;~w)
G ÷ G*
= 0.
in
to
~:K + K
of d i m e n s i o n M.
Let
since the embedded 1M
is
is given by
is a h o m o l o g y
n+l = 2k+l, and let
(k-1)-spheres
(M x I;M x 1,M x 0 u ~M × I).
Kk(~+X;~,)
¢12+X
fi'"
Since
equivalence
A.
is the kernel
the trace;
form on
and the map
÷ Kk(X,8+X;~). ~l(~+X ) m ~.
X'
equivalence
is r e p r e s e n t e d
let
X = M × I~handles
Now let
and
so that
were trivial,
Kk(X;~)
r
xCLAn+l(~Z).
fi
isomorphic
over
x I)
so that
Then the i n t e r s e c t i o n
k > 2,
x
1.6.3,
for some
Since the embeddings
Let
~($) = x.
with basis
to an e m b e d d i n g
be a connected,
is a h omolosy
A, and
As in T h e o r e m
Let
~ = ~l(M).
be embeddings
~(F i) = pi~(ei),
l:M ÷ M
in
n+l = 2k.
fi:S k-! x D k ÷ Int M i=l,...,r.
Mn
÷ (M × I;M x 1,M x 0 ~ M
with t o r s i o n
Hermitian
Let
and a normal ma p
is the identity map,
over
and
Theorem).
¢':X'
72
2r.
M'
represent
Do surgery on
be the resultant
spheres were trivial,
+ M x I.
Then b x the
2r
Kk(X';~)
spheres
is a kernel,
S k x i,I x S k.
images of
1 x Sk
under the map
v i = ui~a
i
u i E Kk(X')
ui
for
are r e p r e s e n t e d
on these embeddings X = X'~X"
and
by disjoint and let
a.
X"
Let
with basis given Vl,...,v r
We can write a i £ • P.
The elements
framed embeddings; be the trace.
is the desired manifold.
73
be the
do surgery
Then
4.4.
The Simply .Connected Case. We assume
w = 1
not taken into account,
and compute
as
Wh(l;~p)
Ln(~).
Torsion is
= 0.
Theorem i. 0
n odd or n=4k+2
Ln(Z P) = ~/2E W
P
n=4k+2 and
and
2 eP
2 ~ P
n=4k
P
where
Wp P =
Z/2Z ~) 7J2Z [7./47.
Proof: Suppose K r.
Case i. A
n
odd.
represents
Assume
or
O
~Z/2~ p = 4k+3
that all endomorphlsms
mod E U ± I ( r - I , ~ )
A
is equivalent
with the element
column
of
of
given in [GI],
mod EU_+I(r, ~ )
P
Kr_ I
to a matrix of the form
to a matrix
in the first row and column of
to i, all other elements
[GI].
of the standard kernel
According to a matrix calculation Lemma 2.1,
p = 4k+l
This proof follows Bernstein
an automorphism
inductively
are equivalent
or
P
[~
equal
in the first row or first
0, and the first row and column of
74
R
equal to
0.
~]
Let
A0
be the matrix obtained by deleting the
first rows and columns of we can assume
P,Q,R,
I:
A0 =
and
Thus
S.
By induction,
U±I(r,Z P) = E U i I ( r , ~ )
C0
and so
L2k+l(~)
Case 2.
n=4k.
prime, and
Fp
= 0.
Let
~p
denote the p-adlc numbers
the field of
a field,
p
elements.
for
F
p~2
there is a residue homomorphism
p
a
Then, since
L4k(F) = W(F), the Witt ring of
(called the second residue in
for
F, for
L4k(Q p) ÷ L4k(F p)
[AI0], Theorem 1.6).
Composing this with the functorial map obtained from ÷ @p,
p & P, we get
L4k(Z P) ÷ ~5'2~ if where
~
L4k(~)
2G P
+ L4kdFp).
by sending
Define
(G,l,~)~-+ ~(det l) mod 2,
is the 2-adic valuation. Then there is an exact sequence
0 ÷ Z ÷ L4k(~)
-~ Z / 2 Z ~ ) 0
L4k(]Fp) -~ O.
This is proved in Lam [A!0], Theorem 4.1. L4k(Q) + ~
splits this sequence.
The signature map
The Chevalley-Warning
Theorem ([A24]) and some elementary number theory show that the signature and in
~p,
p 6 P, define an embedding of
~ • ~) L4k(~p). peP
75
W(~p)
~P P
We let
ape ~+
so that
= image of
~p:L4k(Z~p) + L4k~Fp) , and
a p ~ = image of the signature
W(~)
+ ~.
We have if
2 e p
if
2 ~ P, but there the form
is a prime of 4k-i
in
P
ap = if neither
hold, but there prime 4k+l
if
is a
of the form in
P
P = ¢
and
P
Minkowski [K12],
p=2
~/4~
P-3
mod
(4)
Z~/2~ ~ Z~/2~
p-i
mod
(4)
I
~P
The e l e m e n t s
~/2~
8p(G,l,~) & L4k(Fp)
invariants
of the form
for proofs of these
of H a s s e - M i n k o w s k i
are called the Hasse(G,l,U).
statements
invariants.
76
See Anderson,
and a d e t a i l e d
study
Case 3.
n=4k+2.
Suppose
(-l)-Hermitian
form,
anti-symmetric
billnear
so that
= a2~(x),
k(x,x)
~(ax) = 0.
Since
2 J P.
i.e.,
and
form and k(x,y)
2 ~ P,
= W(x+y)
argument
so that
~(e i) -- w(fi ) -- !
consecutive
pairs.
and similarly
to get a sympletic
with
k(ei,e j) = k(fi,fj)
Then G, so
G
G = <e,f>,
argument
is even.
Group these
el' = el + e2
fl' = fl
e2' =
f2' = fl + f2'
e2
e2',...,er',f2',...,fr'
~(e i) = 0
or
is a kernel.
i
in
c(G,k,~)
2 g P, then
shows every
such
, leaving
~(fi ) = 0. is a subkernel
The form
~(e) = ~(f) = I,
If
by the
Then the number of
< e l ' , f 2 ' , . . . , e r _ l ' , f r '>
= i, has
~ ~/2Z
Apply the transformation
obtain
fixed those with
k(e,f)
= 0.
- ~(y),
= Z/2Z.
Define c:L4k+2(Zp) r c(G,k,W) = ~ ~(ei)~(fi). i=l c(G,k,~)
a map
- ~(x)
k(ei,f j) = 6ij.
Suppose
be a
non-degenerate
~:G ÷ Zp/(2)
Zp/(2)
for G, e l , . . . , e r , f l , . . . , f r
Arf invariant
of
(G,k,W)
k:G x O ÷ Zp
Apply the standard basis
Let
~(e,e)
: i, so ~/(2) G
c
= ~(f,f)
= 0,
is an isomorphism.
: 0, and the same
is a kernel.
77
= 0
The groups Kervaire-Milnor construct
[FI].
the Milnor
Let and
np ~ Wp P
an element a degree
Ln(Z)
n
See also
Browder
p e P.
x ~L4k(2p) ,
We now
manifolds.
be an integer,
for
[G5].
in
with
apIn ,
Then
(n,(np)p e p)
k > i.
By Theorem
determines 3.3.2,
there
is
I map
so that
0($) = x.
equivalence
over
The cone of
boundary
~+M.
the boundary, similarly
Theorem
first considered
and Kervaire
~:(M;~+M,~_M)
~.
were
2.
÷ (S 4k-I x I,S 4k-I x I,S 4k-I x 0)
Now ~ ~+M,
~+M ~ S 4k-I x i
and so
~+M
C(~+M),
is a homology
is a Poincare
Define the Milnor
Poincare
C(3_M)~MUC(~+M).
using
Define
sphere
complex
over
over
complex
by coning
Kervaire
manifolds
x~L4k+2(~).
There are Poincare
k > l, and normal maps Hasse-Minkowski
is a homology
complexes
M + S 4k
invariants
with
np, and
k > 0, and normal map_ss K + S 4k+2
78
over
~,
signature PL-manifolds
M 4k, n
and K 4k+2,
with Arf invariant
I.
~
with
Theorem
3.
Let
H
be PL or TOP.
Then
~n(G/H)
a Ln(Z),
n > 5. Proof:
By T h e o r e m
is generated
3.2.3,
by the Milnor map
and the Kervaire map 0
if
n
~n(G/H) *-+ NIH(sn). M 4k ÷ S 4k
K 4k+2 ÷ S 4k+2
is odd.
79
if
if
But this n=4k
n=4k+2,
and is
4.5.
The Exact
Sequence ' of Sur~er~.
An important of Section closed,
4.3 is the exact
simply connected
Sullivan
~pH(X)
M
if there
is an h-cobordism
between
M0
fl" in A
Here
and X
case,
modulo
the relation
over
i.
provided Proof:
X
~pH(X)
as elements
maps.
The map
let
¢la+M
A,
F:W ÷ X
f0
and
surgery
over
Zp
with torsion The subgroup
of
sequence
÷ [X,Gp/H] ~pH(X)
obstructions. Then there
equivalence
÷ Ln(Zp~)
of dimension
n >. 5.
is defined
are represented in general)
To define
by Theorem by normal ~
is defined
~,
is a normal map
M) ÷ (X × I;X × I,X × O)
a homology
extending
to be normal.
(not a homomorphism
x g Ln+l(Zp~).
¢:(M;a+M,a
in
÷ [X,Gp/H]
is an H-manlfold
3.2.3,
by taking
f0 ~ fl
Zp, W, with torsion
complex
is an exact
+ ~pH(X)
The map
~ = HI(X),
from the notation.
There
Ln+l(~pW)
[HI9].
equivalences
AEWh(~;Zp),
A, and all maps are assumed
Theorem
In the
P = ¢, is due to Wall
in
M1, and a map
is a Poincare
is suppressed
of surgery.
be the set of homology
is an H-manifold,
theorems
P = ¢, it is due to
Zp, f:M ÷ X, with torsion
where
of the surgery
sequence
case,
[GI3]; the general Let
over
corollary
over.
80
with Zp
~(¢) = x
with torsion
and in
A.
~(x) = the class of
Define
¢la+M
in
~pH(X).
In fact, this procedure defines an action of Ln+l(~) over
on
~pH(X),
by taking a homology
Zp, f:N ÷ X, and doing as above to
homology
equivalence
a+M ÷ N.
equivalence
N, getting a
Composition
defines the
action. Exactness
in the theorem then means that
m
induces
a bijection of the orbits of the action to the kernel of o.
This is the content
of Theorems
81
4.3.1 and 4.3.2.
Chapter
5.1.
Handle S u b t r a c t i o n
5.
Relative
and Applications.
In this section we use handle dual to surgery,
Surgery.
subtraction,
to prove a general relative
w h i c h forms the basis
for the geometric
an operation
surgery
formulation
lemma of surgery
groups. Let ~r(@)
~:(N,M)
÷
(Y,X) be a map of pairs
to be the set of homotopy
classes
~
(Dr,D+r-I )
(N,M)
-~
(Y,X).
then each ~ ¢ ~r+l(@) of immersions
contains
determines
M and @ is a normal map, a regular homotopy
f:(DrxDn-r,sr-lxDn-r)
by the relative class
of diagrams
(Dr-I S r-2)
If N n is a m a n i f o l d w i t h boundary
immersion
÷ (N,M)
classification
an embedding,
and define
class
for r < n-2
theorem
([B3]).
If this
let
N O = N - Int f(DrxD n-r)_ M0
:
Since ~ s ~r+l(~), more
~ induces
~0:(N0,M0)
~r+l(~0 ) = Wr+l(@)/<~>.
attaching
Theorem where
~ N O.
i.
an (n-r)-handle
triad over
(Y,X).
Further-
N and N O are cobordant
by
to N0xl.
Let ¢:(Nn;M,M+)
(N;M,M+)
÷
~s a m a n i f o l d
~ p with torsion
÷
(Y;X,X+) triad,
be a normal map,
(Y;X,X+)
in A C Wh(w; ~ p ) ,
82
is a Poincare w = Wl(X)
~I(Y), over
induced by inclusion, ~ p with torsion
r el M+ to a homology
Proof:
in A~ and n ~ 6. e~uivalence
Even-dimensional By Corollary
4.2.1.,
By Theorem
~p~
theorem,
~:(N,M)
immersions
÷
otherwise
el,...,e r. ~ ~k+l(~) ~ ~ p ,
Thus the elements
f!:(DkxDk,sk-lxD k)
qe i s ~k+l(~)
Wl(N) , the maps embeddings
+
(N,M);
where
U =
fi' by Corollary
subtraction:
~fi(DkxDk).
and H,(~)
•
..
Since
homotopic
Let
Let C,(~)
~I(M) m
to disjoint
N O = N - Int U, M 0 = ~N 0, be the chain complex of 4,
of ( Y , N U X )
= H(C,(~))
if using coefficients). exact
f! rep-
1.6.2.
given by the chain complex inclusion,
ei
i
for some q s H(P).
fl! are regularly
Do handle
noted.
By adding trivial handles,
Kk(N,M)
(Y,X).
= 0 for
i
resents
in A.
~IN is k-connected
Ki(N,M)
unless
is s-free.
By the Hurewicz
determine
~ p with torsion
By duality,
it is free with basis
where we regard
Then ~ is cobordant
we may assume
coefficients
2.1, Kk(N,M)
we can assume
over
equivalence
case~ n = 2k.
and ~IM is (k-l)-connected. i # k and we use
~IM+ a homology
i~ ~ is replaced by an
(tensoring
as in Section
For any coefficients
1.2
there is an
sequence
÷Hi(N,M)
By Theorem
>Hi(Y,X)
~ Hi(C)
3.1.2, Hi(~)
÷ Hi_I(N,M)÷.--.
= Ki_I(N,M).
chain complex
defined by
D i = Ci+l(~) ®
Hk(UUM,M)--~
Kk(N,M) , and it follows
83
~p~.
that
Let D, be the We have
C,(UUM,M)®~pW in A.
As
÷
(N0,M 0) ÷
equivalence in A.
By P o i n c a r e
C,(X) ®
over
Odd-dimensional We
over
~p
with
case~
so
~(~IM)
obstruction
we have
÷
with
C,(Y,X)
® ~pW
torsion
÷
that
@0:(No,Mo)
÷
a chain
torsion
C,(Y) ® ~ p W C , ( M O) ® ~ p W
(Y,X)
÷
is a h o m o l o g y
in A.
~ as a n o r m a l = 0, since
torsion
in A.
Let
has
from
~IM to
is a h o m o l o g y
~ denotes ¢:Q ÷
equivalence
~ Y~Xxl
cobordism
~IM+
Here
in L An_l ( ~ p ~ ) .
@ U@:NUQ
torsion
n = 2k÷l.
to a h o m o l o g y
Then
with
is an e x c i s i o n ,
it follows
Thus
can r e g a r d
with
cobordism
~p
equivalence
C,(N O) ® ~ p W
and
is also.
equivalence
and
duality,
equivalence
~pW
~IM+,
(N~UuM)
C , ( N o , M O) @ ~ p W
is a c h a i n
A.
D, is a chain
the
equivalence
surgery
Xxl be a n o r m a l
over
~p
with
a well-defined
torsion
in
obstruction
x ~ L~(~p~). Let Then is
@:R ÷
~(@v¢~@)
relative
over
~p w i t h
as a c o b o r d i s m over
~p
with
For [GI8] The
for
proof
Shaneson
a normal
= x - x = 0, and
cobordant,
alence
Xxl be
of
the
the
case
case
of the
torsion
with
~(~)
= -x.
so C u C u @ : N U Q U R
to the b o u n d a r y ,
(N,M)
torsion
map
in A.
~ Y~Xxl
to a h o m o l o g y
This
equiv-
can be r e g a r d e d
rel M+ to a h o m o l o g y
equivalence
in A.
P = ~, this
~ = I, and
theorem
[HI9]
odd-dimensional
for
case
[K5].
84
is due the
is due
to Wall,
general to
case.
Cappell
and
5.2.
Geometric Definitions
of Surgery Groups.
In this section we define surgery groups in a more general context and relate them to the algebraic definitions given in Section
4.3.
To do this we need the notion of an
n-ad. Let
C
an integer.
be a category of spaces and maps and n ~ 2
Define
~(n) to be the category with objects
X = (IXI;X1 . . . . ,Xn_ 1) Xi C
IX], and
X(a) = O
c { 1 ..... n-l} and morphisms
between
, is an object of
X and Y given by a map
so that f(X(a)) C Y ( ~ )
for each
a.
f:IXi
We let
~. : ~(n+l) m
÷
~i' 6i, and Sn, k by:
e(n), ~ X i ~ Xj
l~iXl = Xi" (~iX)j = 6. : ~(n+l)
[XiNXj+ I
j > i,
.~ ~(n)
Z
J l$iXl = IX1, (6iX) j =
(~(n) Sn,k:
j < i
Iv j j+l
<
i
j > i,
c(n+k) ÷ ISn,kXl = IXI'
(Sn,kX)j
=
{~j
jj <> nn.
n-t Define
~X(a) =
~
X(6).
In particular,
85
~X = ~ X . .
C
* IYI
X{1,...,n-i}
This is called the category of n-ads associated to Define functors
Xi,
G.
= IXI.)
If f:X ÷ Y is a map the
induced
n-ad
and
map;
similarly
Y is a space,
of n-ads, for
define
6i'
let
~ and
an n - a d
$if:~i X ÷ ~i Y be Sn, k.
XxY by
If X is an
IXxYI =
IXlxY,
(XxY) i = XixY. Let ad X' by [C;A,B]
X be
IX'I
Wm(X,Xo)
manifold
with
a ring)
a Poincare
~ A,
Define
an
(n-l)-
X!l = [Xi+ l ; X l ~ X i + l , X o ] ~(i)
M is a m a n i f o l d
boundary
~ B]
for A , B C C .
where
(-~
A map
, where Define
X'o is the
constant
= j,
class
X is a P o i n c a r e
[X(~),ZX(~)]
k ~ (-l)t[x(~-it)], t=l
Poincare
= [Y(~),~Y(~)]
~/2~).
category
of n o r m a l
manifold
n-ad
M and
functors
further
is a n-ad
~ ={i I ..... ik} , ( X ( ~ ) , ~ X ( a ) )
fundamental
Let ~ be a p a i r
omit
M(~)
is
so that
where
~X(~)°
if ¢ , [ X ( ~ ) , ~ X ( ~ ) ]
the
if each
An n - a d
}:X ÷ Y b e t w e e n
and w ~ H I ( I K I ;
n-ad
~M(~).
if for each
pair with
k j: ~ J X ( ~ - i t) t=l
we
s X(~).
O
= Wm_l(X',x~)
~[X(~),ZX(~)]
under
x
at x o and m _> n - i. An n - a d
(over
with
= [IXI;Xl,Xo],
= {~ s CI:~(0)
inductively path
an n - a d
maps
for e a c h
is of d e g r e e
where
Let
be a s u b c a t e g o r y
C
of d e g r e e
2, ~i"
Here
K is a CW
(n-l)-ad of the
~ ~:M ÷ X, b e t w e e n
n-ad
X over
H = TOP,
of it.
86
i
~.
(K,w),
a Poincare
mention
n-ads
a ring
PL,
an H-
R,
or DIFF,
closed and
Define ~ ( ~ )
to be the cobordism group of C
~, where we regard a map w : X ÷ Sn_l,iK
so that
(~:M ÷ X) ~ ~ as a map of n-ads
Wixi = ~*w, where Wlx I is the o r i e n t a t i o n
class of IXI, and we use the boundary
operator
Thus M I ~ X I + ~ and M 2 ÷ X 2 ÷ ~ are bordant maps
of (n+l)-ads
N ~ Y ÷ Sn_l,2K as above
~n N ÷ ~n Y + ~nSn_l,2 K = Sn_l,iK and similarly
applying
~iso require
compatible
~m(~)
denotes
category.
~n-i yields
in A.
Define ~m(H) and
~m(H)
so that
relation ~
the full of
IMI.
R is a ring and A is a selfDefine
of homology
Qm(H)
= ~(~)
equivalences
= ~IhHQm_I(H),
where
Define
where
over R with
is a natural map hH:Qm(H)
= h~l~n~lhHQm_l(H).
Note we
for Y as above.
the d i m e n s i o n
of W h ( w I ( I K I ) ; R ) .
There
if there are
to M I ÷ X I ~ Sn_l,l K
the group defined above with
is the s u b c a t e g o r y
~n-i + ~n"
M 2 ÷ X 2 ÷ K.
orientation
Let H = (~,R,A) where
torsion
is equal
The integer m denotes
dual subgroup
over
÷ ~m(~).
~n_l:~m(~)
~(H)
and
÷ ~m_l(~),
~(~)
similarly by r e q u i r i n g that ~ : 6 m _ i X + K induce isomorphisms on f u n d a m e n t a l responding
groupoids
intersections
on each component. also assume
(that is, for each ~ the corhave
isomorphic
This will be made
X is connected,
fundamental
clear later.);
and w~ require
groups we
the same for
cobordisms. There is a natural map Lm(H)
to be ~m(H)/image
There
is a natural map L~(H) ÷
no natural
group
of
~m(H) ÷
~m(H);
87
and we define
define L~(H)
Lm(~);
structure.
~m(~)
similarly.
h o w e v e r L~(~)
has
The the next
n-ad
Suppose
Let K be an
(n-l)-ad
the
corresponding
in 6 n _ i X
(and c o n s i s t e n t classified
orientation
class
Theorem
i.
With
m - n ~
3~ then
equivalence if the
Proof:
class
Suppose
a homology
first
that
~N = M U M + ,
f:N -
f(M+)
with
n = 2. ~p,
~M + I be a U r y s o h n
= i.
Define
Let
if
the
class
of
Now there
~
is
are
of the
spaces
Then an
di m M
= m~
and
to a h o m o l o g y in A if and
only
vanishes.
Assume
~ is c o b o r d a n t
~ X, by
to
a cobordism
= ~M = ~M+.
(x,0) ~ (x~t) function
for x E ~X, t ~ I.
with
f(M)
= 0,
~:N ÷ Y by
~(x)
@:(N;M,M+)
that
maps).
I(~'(x),f(x))
Then
torsion
H = (K,w, ~ p , A ) .
torsion
~+:M+
MAM+
where
torsion
subspace
groups
in
between
S n _ l ~ i K , and d e f i n e s
i_nn L~(H)
over
with
inclusion
qRbordant
~p
M ~ X + K
Let Y = X x l / ~ Let
X ÷
map
with
and e a c h
as above~
over
equivalence
~ ' : N ÷ X, w i t h
the
¢ is n o r m a l l y
of
is s h o w n
(Wl(~n_iX),l),
w in H I ( I K I ; ~ / 2 Z ) .
of n - a d s
~p
fundamental
with
by a map
~p
over
space
to the
notation
L~(H)
over
of type
total
K(~,l)'s
W i x I is
n-ad
equivalence
(n-l)-ad
so that
set
@ : M ÷ X is a n o r m a l
and a P o i n c a r e
~n_l @ a h o m o l o g y
in A. an
of the r e s t r i c t e d
theorem.
a manifold in A,
value
=
(Y;Xx0,Xxl)
M ~ X vanishes suppose
is a c o b o r d i s m
the
class
x I
~'(x),0)
is a n o r m a l
~H
x ~ ~H.
map
and shows
that
is L~(H). of M ÷ X ÷ K v a n i s h e s .
@:(N;M,M+)
÷ 88
(Y;X,X+)
Then
to a h o m o l o g y
equivalence
@+:M+
Furthermore, that Wl(X)
+ X+ o v e r
Wl(X)
m Wl(K)
surgery
suppose
and
in A).
it follows
easily
by i n c l u s i o n .
we
over
remainder
surgery
the
can do s u r g e r y
~p.
on n-ads. torial
has
of the
been
procedure
Thus
Lemma
torsion
on ~ to get
In p a r t i c u l a r ,
we
a
can do
on ~ : M ÷ X. The
apply
5.1.1,
equivalence
(with
~ Wl(Y),
m Wl(Y) , i n d u c e d
By T h e o r e m homology
~p
We now
properties
i.
Let
Poincare
pair
show
¢:(W~V) over
extension
÷
on M(B)
that
L'(H) m
has
L~(H)
÷ (Y~X)
Wy
= wo~#:~l(Y) Then
(Z;Y,Y+),
theory
for
nice
group
be a n o r m a l
with
torsion
there
in A~
map~
Then
surgery and
func-
(Y~X)
a
dim W = m ~ 5,
+ Z/2Z.
= V, Y ~ Y +
of ~, ~:Z ÷ K so that
~.
is a b i j e c t i o n .
Assume
is a n o r m a l
W~W+
B c
(M(~),~M(~)).
~ Lm(H)
~p
by i n d u c t i o n :
for each
to the p a i r
by p r o v i n g
2-skeleton.
¢, @:(U;W,W+)
follows
is an o b s t r u c t i o n
and ~:Y ÷ K so that a finite
done
above
L~(H)
theorem
K has
cobordism
= X, and
( ~ I Y + ) # : w I ( Y +)
of
an
÷ Wl(K)
is an i s o m o r p h i s m .
Proof:
By T h e o r e m
dim(Y0~
X) ~ m - 2, and H is o b t a i n e d
1-handles. If
The
inclusion
~ is the
TH + ( ~ I H ) * ~
3.1.3,
line
is t r i v i a l ,
we
can
assume
induces bundle so we
Y = Y0 V H H'
from
D m by
a surjection
over can
8g
K defined
do s u r g e r y
XCY0,
adding
~I(H)
+ ~I(Y).
by w,
then
on
~IH:H
~ K
to get H' ÷ K w h i c h
induces
an i s o m o r p h i s m
on f u n d a m e n t a l
groups. Let
J be the
Z0 = Y0xlUJ, for
Y+
Since
thus
is also
and
U, we
onto
consider
1-handle sphere
Z = Z0/~
extends
S O and
of each
(~IY+)# so
and
define
, where
over
(x,t)
J, we
~ (x,0)
get
a map
such
pair
2-handle
but and
case.
r ~ K(P)
wI(K)
is an
SO =
{a,b} with
S ~ @-I(s0),
÷ Wl(Y+)
one
To
regular
and so the
construct
at a time. to the
T = ¢-I(H).
and
choose
total
embedded
Then
multiplicity
Xl,...,Xr8
multiplicity
i.
@.
of S in c o m p l e m e n t a r y
opposite extend Let
components
by paths,
S = @-I(sI)
can assume
S I x D m-I
degrees.
Attach
We
handles
can now
pairs
to
arrange
having
a handle
we
the
(assuming
W is c o n n e c t e d , can
assume
r ~ H(P)
+ S l x l n t ( D m-l)
gives
Add
@ -l(a),
the
along
each
@.
÷ S I is of degree
which
taking
xi,Y i and e x t e n d
We
to Wxl,
~I(H')
of S O is r.
regular).
embedding
~#~
But
@ is t r a n s v e r s e
degree
points
image
of J,
Let
containing
same
~I(Y+)
is an i s o m o r p h i s m .
to H.
y l , . . . , y r s @-l(b)
other
+
is onto.
(~IY+)#
Assume
component Write
~I(H')
the h a n d l e s
case.
@IT:T ÷ H has
@IS:S
~IH
constructions
isomorphism;
the
and
surgery,
K. By
discs
of the
= YO U H ' ,
x ~ X, t a I.
2:Z ÷
trace
so by j o i n i n g
so is h o m o t o p i c
of d e g r e e
90
and
S is c o n n e c t e d .
and
result.
@ is t r a n s v e r s e
r.
Add
Then to an a handle
Theorem
2.
If m - n ~
then Lm(H) + Lm(~)
Proof:
Follows
Corollary if m >
i.
3 and
IKI has a finite
2-skeleton,
is a bijection.
immediately
L~(K,w; ~p)
from the lemma.
is isomorphic
to L ~ ( ~ p W l ( K ) )
5.
It follows isomorphic abelian. H = TOP, Theorem
defined
Note also that though
~n(H)
4.3.2,
2.
Lm([)
we need only
space
modules;
group,
consider
since which
it is is
and f~n(Z) depend
is independent
of H.
on
Also, by
normal maps with
a manifold.
Let R be a principal
and R ~ Z / p Z
is abelian,
to the geometrically
PL, or DIFF,
the target
Lemma
A ~p~) that L2k+l(
= 0}.
ring,
and P = {p:p a prime
If C is a chain complex o f
then C(9 Z~p~ is acyclic
free
ZZ~
if and only if C ~ R ~
i_s_s
acyclic. Proof: C®R
free,
Since
C~R~
is acyclic,
--- ( C ~ g R ) ~
and similarly
Now suppose
C~
0
Z~p)
= Hi(C~
Z~,
we need only show that
for
Zp.
2Zp is acyclic. --- Hi(C) (~ Z~p.
Since
Thus H i ( C ) ~ R
So we have Hi(C~R)
"- Hi(C) ® R
(~
= Hi_l(C)*R.
91
Z p is torsion
Hi_I(C)*R
= 0.
Thus
the p r o o f
is r e d u c e d
A,R
= 0 for A a f i n i t e l y
and
* commute
exact
with
to s h o w i n g
generated
direct
sum,
abelian
we
A@R
= 0 implies
group.
can a s s u m e
Since
A = ~/n~.
The
sequence n
0 ÷ is a free
~
÷ ~
+
A
presentation
~
0
for A so we h a v e n
0 Thus
+
A*R
~
R
÷ R
÷
A®R
~
0.
A*R Z R/nR A®R.
Conversely, so H i ( C ) ~
Zp
= 0.
if C ® R So
is a c y c l i c ,
C @ Zp
= @,IA,
unique
where
¢,:Wh(~;
Define
LmA(w,w;R)
denote
L A
for
m
We n o w promised
where
clarify
is for e v e r y
commute.
~: ~ p
the
Let
e
The m a i n
~ c
+ w(~)
example
= Wl(K(~))
K(w,l)
the
so that
is i n d u c e d
We
•
let
nonsense
category
2 n is
by
the
Lm h, L m s
for
of f i n i t e l y
B C~
so that an
Wl(K(w,l))
92
2n = w.
in
is a g r o u p o i d
generated ~(n+l), w(~)
and w = Wl(K)
÷ Wl(K(~)).
then there This
as
all d i a g r a m s
(n+l)-ad
f ~ = i#:Wl(K(B))
of type
of n - a d s
an o b j e c t w
there
is if K is and
let
0.
(l,...,n)
If ~ is a g r o u p o i d (n+l)-ad
Wh(w;R)
algebraic be
of W h ( w ; R ) ,
+ R.
of type
f B:w(B)
~I(K)(~)
+
= Lm A'(K(w,I),w;~)
A groupoid
and m o r p h i s m s
subgroup
A = Wh(w;R),
earlier.
groupoids. that
~p)
ring homomorphism
= 0, and
is a c y c l i c .
So if A is a s e l f - d u a l A'
Hi(C) ~ R
is an
is d e f i n e d
as
follows:
the
K(~,I)(~)
=
components ~_~ i
of w(~)
K(Gi,I)
are g r o u p s
and m a k e
the
our main
theorem:
Gi,
so let
corresponding
maps
inclusions. We
T h..e.... o..r e m rin~
can n o w
3.
Let w be a ~ r o u p o i d
and ACWh(w{I,...,n-2};R)
there
are
@:M ÷ X ension
surgery
s L m(W;R) A
Zn_l M to
torsion
Assume
the K.
are
~(~)
the
2 n-2 ~ R a p r i n c i p a l subgroup.
L~(w;R)
a manifold
X over
equivalence
so that
rel
R with
Proof:
n-ad
over
= 7, m - n _> 3, t h e n
cobordant over
srqups
map b e t w e e n
m and a Poincare
Wl(6n_iX)
of type
a self-dual
obstruction
is a n o r m a l
~n_l @ a h o m o l o g y
~(¢)
state
R with
R with
there
so that n-ad
M of d i m -
torsion
torsion
if
in A,
in A,
is an o b s t r u c t i o n
= 0 if and
a homolo@y
Then
onl~
if
equivalence
% is n o r m a l l y of, n - a d s
in A.
n = 2.
Define
components
L~(~;R)~
=
@
A L~(Ki;R)
where
i of t y p e K ( w , l ) .
of a s p a c e
i
If R =
~p,
the
R arbitrary,
result
the
X is a P o i n c a r e Let
C, the m a p p i n g Poincare and over
~p
surgery
and
will
over
s Hm(X;~) cone
complex
so C, @ ~ p
result n-ad
[X]
follows
chain
over
be
over
the
complex
is a c y c l i c .
problem
follow
i and
from Lemma
2.
For
2 provided
~p.
R with
is e a s i l y
from Theorems
seen
(w,R,A)
fundamental of
[X]~.
torsion
in A,
Thus
X is
to h a v e
Since
torsion
and X is a
C , @ R is a c y e l i c
a Poincare
is e q u i v a l e n t
93
class,
complex
in A'.
Thus
to a s u r g e r y
a
p r o b l e m over (w,~P,A').
This gives the result.
The n-ad case is similar. h o m o m o r p h i s m w was s u p p r e s s e d
The t h e o r e m works
Note the o r i e n t a t i o n
from the notation.
for any ring R that satisfies
Lemma 2. Torsion example, ~/2~ •
5.3.
for arbitrary
let R = ~'/ ~',
rings
~[x,y]/(x2+y2-1). but Wh(l; ~p)
Classifying
Spaces
spaces
groups,
groups,
notably Let
~
Then Wh(I;R)
for Surgery.
classifying
as was first done by Quinn
to painlessly
For
= 0 for any P ([D20]).
In this section we define surgery
can be bizarre.
derive
sequence
be a small c o b o r d i s m
for
[H8], and use these
some properties
the long exact
spaces
of surgery
of surgery.
category
(Stong [AI6])
and define a A-set by ~,~(A k) = the set of (n+2)-ads maps If
C
is graded
in
~, with face
induced by face maps
(e.g. manifolds),
of objects.
then define A ~
~n (Ak)
= those elements
in ~,G(Ak)
of d i m e n s i o n
k+n. De fine ~n e
= Sx~(~ne)
According
to Prop.
1.4.4 of [H8], ~r(~ 94
7) ~
an+r(C),
the (n+r)-th cobordism group of the category
~.
~ n~ n -~ -i" It follows that given H = (~,R,A) as
Also
C n
is an infinite loop space, ~
5.2, there exist classifying spaces ~m(~)
~- ~m+j(H)
in Section
~Hj and ~'3 so that
and ~m(#~Hj) = Image(~ m+j(~) ÷ ~m+j(g))"
There is a natural map H+~H ~J j" Let ILj(H) deonte the fiber of the map ~ Hj-i ÷ ~ j -i"
Theorem i.
~j(H)
is an infinite loop space with
Wm ( ~ j ( H ) )
~ Lm+ j(H) .
Define 3i H = (3iK,R,A) where
~i ~ = (3iK,WlWl(l~iKl))
and similarly for 6.K. Then there are natural maps i ~j(~i H) ~ Lj(6iH) ÷ ~j(H), which is, up to homotopy, a fibration.
Thus by the long exact homotopy sequence of
a fibration, we have
Theorem 2.
There is a long exact sequer~qe
• ..÷ LA(~iK;R)
÷ LA(~i X;R) ÷
LA(K;R)
÷
LA_I(~i ~;R)~''"
These ideas are more fully expounded in Quinn's thesis,
[HS]
and in an article in the Georgia Conference on the Topology of Manifolds.
See also section 17 in Wall [HI9].
95
5.4.
The Periodicity
T h e o r e m ~ Part I.
Let N n be a closed orientable xN:Lm(H)
+ Lm+n(H)
manifold
by sending M + X to MxN ÷ XxN.
easy to check that this is a w e l l - d e f i n e d
Williamson
[H20] and S h a n e s o n
show that
xCP 2 is an i s o m o r p h i s m The general
Recall that L mA ( Z p W )
T h e o r e m i.
[HI0].
[HIg],
In this section we
for the non-simple
case,
case will follow in Section
x@p2:L~(~,w;R)
÷
Lh
--
R =
in W a l l
6.3.
A ~p~). = Lm+4(
For m > 5,
an isomorphism;
It is
homomorphism.
For R = Z, this map is d e t e r m i n e d partially
A = Wh(w;R).
and define
(w,w;R)
is
m+4
--
coinciding with the i s o m o r p h i s m
above if
Zp.
Proof:
Even d i m e n s i o n a l
case~ m = 2k.
Let ~:M ÷ X represent Assume
as in Section
throushout, free.
5.2 that ]~ =
we can assume
Then,
representing
Zp.
x e ~L~(~,w;R). Using R~-coeffients
~ is k - c o n n e c t e d
algebraically,
form on Kk(M).
an element
and Kk(M)
x is r e p r e s e n t e d
by a H e r m i t i a n
Let fi:SkxD k + M, i = l,...,r,
a basis
be immersions
for Kk(M).
M u l t i p l y i n g by {p2, the only n o n - v a n i s h i n g groups
are Kk(MX@p2),
isomorphic
Kk+2(Mx@p2)
and Kk+4(MxCp2),
kernel all
to Kk(M).
Let j:S 2 ÷ {p2 be an embedding generator
is
of ~2(~P 2) ~
~.
Define
96
representing
gi:skxs 2 ÷
a
MxCP 2 by
(fi,J) > MxCP 2, and assume they
skxs 2 SkxDkxS 2 (x,y) ~-~ (x,l,y) are in general position.
It follows easily from Theorem 1.1.6 and Spanier Chapter 5, that X(fi,fi,)
= ~(gi,gi,)~ ~(fi ) = ~(gi ) since
j is an embedding representing a generator. gi(Skxl)
[AI5],
The spheres
are disjointly embedded and framed, so we can do
surgery on them, obtaining a manifold N. of the surgery
and 9:N ÷ X.
Let W be the trace
Then k(MX@p2)
I~
Ki(W,Mx@p2 ) = and so Ki(W)
i = k+l otherwise
= 0 for i # k+2~ k+4.
We have Kk+4(Mx@p2)
--" Kk+4(W ) +
Kk+I(W,MxCP so Kk+4(N)
Kk+2(N)
Kk+4(W,N)
2)
Kk+l(W,Mx~p2)
= 0, and the only non-vanishing kernel is
~ Xk(M). Surgery on the spheres Skxl yielded immersions
hi
:sk+2
~ MxCP
2
; furthermore
~(hi,h j) = ~(fi,fj),
~(fi ) since the spheres gi(Skxl) Clearly the maps h i represent
~(h i) =
are disjointly embedded.
a basis for Kk+2(N)
and
correspond to the fi under the isomorphism Kk+2(N ) ~ Kk(M). Also, Kk+2(N ) ~ ~k+3(~ ) and so the h i are framed.
Thus
the surgery obstruction for Mx~P 2 ÷ Xx@P 2 is represented by the Hermitian form on Kk(M). 97
Odd-dimensional
case~
x s Lh(w,w;R),
R = Zp,
algebraically Kk~I(~U),
2k-l:
and as in Section
by the subkernels
Kk(U,~U)
generators
fi disjoint
and Kk(M0,~U)
in
in Mx@P 2 to get a manifold N. the surgery yields
from sk-lxs 2
÷ MxCP 2.
But Kk(M,U)
are disjoint
spheres
fi(sk-lxl)xpt.
Then Kk_I(N)
= 0, and as
framed embeddings
gi:S k+l +
N
Let W be the trace of the surgery.
~ Kk(MX@p2,u)
~ Kk(M0,~U),
framed spheres
re-
The maps gi generate Kk+I(N) ~
Kk+I(MXCP 2) ~ Kk_I(M). Then Kk(W)
embeddings
of Kk_I(M) , M 0 = M - Int(U).
Do surgery on the embedded
above,
4.3, x is represented
where
r U = ~ fi(sk-lxDk), i=l resenting
Let ¢:M ÷ X represent
m Kk(M,U);
so Kk(N)
representing
is free.
a basis
from the gi(sk+l);
also Kk(N) ~ Kk(W). Do surgery
on
and assume these spheres
let Q be the resultant.
Clearly
~
i = k+l, k+3
LO
otherwise.
Ki_2(M)
Ki(q)
=
The embeddings
gi determine
embeddings
gi ) in Q; these maps generate Kk+I(Q) r V = ~gi(sk+ixD i=! fi(sk-lxl) isomorphism
k+2) C Q.
~-~ gi(sk+Ixl), of kernels.
(also denoted
~ Kk+I(N).
Then the map Kk_I(~U) fi(ixsk-l)~
is an
sends Kk(U,~U)
Kk+2(V,~V) ; we must show it sends Kk(M0,~U)
98
÷ Kk41(~V),
gi(ixsk-l),
This isomorphism
Q0 = Q - Int(V).
Let
to
to Kk+2(Q0,~V),
To this end, note we have
Kk(M !,~U) ÷ Kk+2TM0xCp2, 2 )a2$~UxCP Kk+2(MxCP~UxCP 2) Kk+2(MxCp2,UxD) where
~ Kk+2(MxSP 2- UxD,~(UxD))
D is a regular n e i g h b o r h o o d
on the fi inside each component (the S 2 comes
of w h i c h has the homotopy
of the triple
and
We can assume V C Int(V'). induces
isomorphisms sequence
(V';V,V'-Int(V);~V).
+
~ Kk+I(~V')
Kk+I(~(UxD))
by the fact Kk+I(UX~D)
and the map
is an isomorphism.
= 0 since
(It is onto
~D + S 2 is the n o n - t r i v i a l
~D = S 3 and the homology
free of the same rank, identify
as before
seen by the M a y e r - V i e t o r i s
Now Kk+I(~(UxD))
sl-bundle,
sphere).
of ~V and ~V' in V' - Int(V)
) as is easily
Kk+i(~Ux@p2)
type of S2vSk+Ivs k+3
from D, the S k+l is c o n s t r u c t e d
The inclusion
Doing surgery
of UxD instead of UxCP 2 we get a m a n i f o l d V',
the S k+3 is the transverse
on Kk+l(
of S 2 in ~p2.
sequence.
it is an isomorphism.)
Kk+2(Mx@p2-1nt(UxD),~(UxD))
Since both are Now we
~ Kk+2(N - Int(V'),3V') K k + 2 ( N - Int(V),~V) Kk+2(Q0~3V).
This
concludes
the proof.
99
Theorem
2.
If K is an n - a d
an i s o m o r p h i s m
Proof:
L~(K,~;R)
Immediate
and T h e o r e m
by
~
and m - n > 3~ then
x~P 2 is
Lh (K,w;R) m+~
induction,
the
I.
100
five
lemma,
Theorem
5.3.2
Chapter
6.1.
The
Long
6.
Relations
Exact
Between
Sequence
of S u r $ e r y
Let w be a m u l t i p l i c a t i v e homomorphism.
For
is a s e l f - d u a l
subgroup
Def.
Let
structions and
0
I.
the
subgroup maps
and w:w
+ {+i}
a
Suppose
A
= L n ( l ; Z)
is an exact
÷ CH A +l(~;R) ~
of ob-
of L~(~;R)
M ÷ X with
(H = TOP,PL,
CPLn(I ,~
There
group,
Coefficients.
let ~ = (w,w).
by n o r m a l
X H-manifolds
For e x a m p l e ,
with
of W h ( w ; R ) .
denote
realizable
M and
Theorem
convenience,
CH~(~;R)
Surger Z Theories.
aM = ~ = aX,
or DIFF).
by T h e o r e m
4.4.2.
sequence
~ n H (~,A,R)
L~7(E;R).~ ~
÷ ~Hn(~',A,R ) -~ LI(E';R ) -~
Proof:
The
terms
follows
~(~,A,R)
exactness from
of this
Corollary
~ ~(Y,A,R).
We
sequence 5.2.1. show
at the
Let
that
last
B denote
ker(B)
0.
four the map
~
Li (Y;R)/CH~+I(~;R) n+l Let equivalence This ~
gives
is the
x s ker(8). over
x is r e p r e s e n t e d
R, M ÷ X, b o u n d e d
a well-defined
equivalence
8. is r e p r e s e n t e d 1
Then
map
relation
by N i + Yi'
by
ker(B)
~ normal
map
+ LA (~;R)/~ n+l
defined i = 1,2,
101
by a h o m o l o g y
by
N ~ Y. where
e I ~ 0 2 if
so that
aN I ÷ aY I
and
~N 2 ÷
3Y2 r e p r e s e n t
Suppose equivalence define
01 ~
over
maps
equivalence
over
Thus
R, the
81 -
02 ¢ c H A + I ( ~ ; R )
eI -
So we h a v e
derived
g:R ÷ R' be
g[f](rx)
rings; w,w'
÷
= g(r)f(x).
of the map Let
so that
9Y I and
g[l],A
C A'.
3Y2' the
W ÷ V is a h o m o l o g y of N ~ Y is
Conversely,
map
ker(B)
÷ LA+I([;R)
calculations
show
that
an i s o m o r p h i s m .
of a u n i v e r s a l A similar
Theorem
5.3.2.
version
sequence
a ring homomorphism,
where
of
can be
R and
let ~ and ~' ~e m u l t i p l i c a t i v e as u s u a l , = w.
Wh(~;R') We w a n t
g[l]:Rw
A, A' be
~N 2 ÷
) and e x t e n d
4.5.1.
so that w ' f
g[f],:Wh(w;R)
groups
if W + V is a h o m o l o g y
02.
and in fact
using
homomorphisms
homomorphism
eI
is sort
~nH(~',A,R).
obstruction
Straightforward
in T h e o r e m
are p r i n c i p a l
Since
a well-defined
sequence
for n - a d s
Let
map
~N I ÷
surgery
implies
is a h o m o m o r p h i s m
sequence
with
in
Then
62 ¢ cHA+I(-~;R).
cHA+I(~;R).
This
R'
bounds
to get N ÷ Y.
62.
the
class
02 as above.
R which
eI -
this
same
N = NILJWLJ(-N2) , Y = YIUVU(-Y2
respective
modulo
the
Then
let
f:~ + ~' be a
there
induced
by
to study
is a ~ / 2 E - e q u i v a r i a n t g[f]:Rw
the
effect
÷ R'w', on s u r g e r y
÷ R'~.
self-dual Let
and
groups
subgroups
H = (w,w,R,A),
102
of W h ( w ; R ) ,
Wh(w;R')
H' = ( ~ , w , R ' , A ' ) .
Using the n o t a t i o n hH~-IhHQm_I(H Define
of Section
=
~ m ( H ' ~H)/g, ~ m ( H ) ,
is the induced map. we can assume
By the remarks
all spaces
=
There is a long e x a c t
following
Corollary
÷ Qm(H') 5.2.1~
sequence L(g)
,LAm( ,w;R)
> ~ m ( g ; H , H ')
where g,:Qm(H)
involved to be manifolds.
j, ...
~m(H',H)
).
~m(g;H,~')
T h e o < e m 2.
5.2, let
, > ~ m _ l ( g ; H , H ') ÷.-..
Proof:
This can be proved using classifying
s h o w i n g that the fiber of the required properties;
~m(W,w,R,A)
÷
spaces and
LLm(W,w,R',A')
we give here an elementary
has
geometric
proof. Define L(g) by sending
to be the functorial map;
f:M ÷ X in L A ' ( w , w ; R ') to the class of ~f:~M ÷ ~X, m
a homology e q u i v a l e n c e
over R'.
be the class of f in L~(~,w;R).
We define j , [ f : M + X] to Elementary
show that these are well-defined. equivalence
L(g)j,
~,L(g)
We
Clearly
if f:M ÷ X is a homology 0 in Lm(W;R').
= 0: ~,L(g)[f:M ~ X] is r e p r e s e n t e d
~X, a homology
(iii).
homology
= 0:
over R', then f represents
(ii).
~f:~M ÷
assumed to be normal.
of A, A', and w throughout.
(i).
by ~f:~M ÷
considerations
Recall that a homology
over a ring is always
omit m e n t i o n
equivalence
2, is defined
j,~, = 0:
equivalence
over R, and thus is 0.
j , ~ , [ f : M ÷ X] is r e p r e s e n t e d
~X in Lm(W;R) , and f gives a b o r d i s m of ~f to a equivalence
over R. ]O3
by
(iv). normal
map,
cobordant f':M'
ker(L(g))
C Im(j,):
f a homology
to a h o m o l o g y
÷ X'.
Then
(v).
~f is cobordant
equivalence
equivalence
j,[f']
ker(~,)
cobordism
property
(vi).
(pg.
[f:H
=
45 in
ker(j,)
C Im(~,):
Then
~,[F]
This
Remarks:
(i) [K9]
L~(~)
to be the
to relate
to change
locally
and
the
now shows
that
in this
This [KS]. epic,
cobordism
by r a t i o n a l case
type was
and L ~ ( ~ ) , group,
to be
Then
the proof.
first
where
used by
he defines
except
h-cobordisms.
is shown
÷ X] = 0.
over R by a c o b o r d i s m
completes
of this
L~(~)
usual
= (~,w,g, Wh(~)),
are
= If].
A sequence
Pardon
and S h a n e s o n
[J22])
Let j , [ f : M
F:N ÷ Y.
(2)
R, the c o b o r d i s m
~ X].
equivalence
~m
If] E ker(L(g)
8X
to a homology
factor
over
over R', F:N ÷ Y,
f is c o b o r d a n t
allowed
i.e.
If ~,[f:M ÷ X] = 0, then
equivalence
equivalence
÷ XOY]
over R, and f is
over R',
C Im(L(g)):
given by a homology
L(s) EfUF:MuN 9N
f:M ÷ X is a
= [f].
to a homology
extension
Suppose
boundaries
The
~%m(H',~),
correction where
Z' = (~,w,Q,Wh(~,~)). is also r e l a t e d In fact, then
to the surgery
of Cappell
if g ~ ÷ R~ and g[l]:R~
~ m ( g ; H , R ') ~ F~+I(~) , where
÷ R'~ ¢ is
the d i a g r a m
and H = (~,w,R,Wh(~,R)) (3)
are
A similar
etc. formulation 104
can be done
for n-ads.
6.2..
The
Rothenber$
In this Rothenberg
with
the p r o o f
Lemma with
section
using
a map
2.3
2.3)
~p w i t h
q:W ~ M so that
Then
A be a kxk m a t r i x
Z~-module
to get
on the
~
identity
on g e n e r a t o r s
~2(~+I(W+,M+)),
so every
Let
A = (aij)
and
be the
over Zp,
factor).
i = l,...,k,
trace and
gives
4.
and M n a m a n i f o l d
Furthermore
representing
there
is
q is a h o m o l o 6 y
Then
assume
W ~ Mxl ÷ M is the
aij
let
Then
map
105
amounts
is r e p r e s e n t e d 5.
(if not,
~
a
=
multiply
representing
(~ixl;Mx0,Mxl)
~ is a h o m o l o g y
over Zp,
q.
this
~2(W+,M+)
on spheres
~:(W;M,M')
an h - c o b o r d i s m desired
E Z~
and
is a free
dim M+ = n ~
Do s u r g e r y
and
since
~2(W+,M+)
Also,
M+,since
Add k t r i v i a l
(W+;M,M+)
in ~ 2 ( W + , M + )
of the s u r g e r i e s . so is
triad
x.
(Mx±;Mx0,Mxl),
element
S2 C
k j~laijej,
of C h a p t e r
i:M C W;
e l , . . . , e k.
embedding
a suitable
= x.
map.
by a f r a m e d
A by
of these
We
is an h - c o b o r d i s m
a manifold
~+:(W+;M,M+)
to s u r g e r y
6.1.
~p.
to Mxl
map
there
qi = I, w h e r e
Proof:
normal
light
T(W,M;~p)
over
2-handles
first
of
to a r b i t r a r y
of S e c t i o n
x a Wh(W;~p)
equivalence
Let
The
sequence
[Hg]
sequence
in the
Let
= w, n _> 5.
over
the
and S h a n e s o n
of lemmas.
of T h e o r e m
~I(M)
generalize
the exact
a series
i (Theorem
(W;M,M')
we
(unpublished)
coefficients begin
Sequence.
T(W,M;~p)
equivalence = x, and
Lemma
2.
Let f:M n +
Zp between
manifolds,
f is c o b o r d a n t ~ homology
X n be a h o m o l o @ y
over
n _> 5; let a E W h ( ~ I ( X ) ; Z p ).
by a h o m q l o s y
equivalence
equivalence
equivalence
over Z p w i t h
Then
over Z p ,
torsion
to a
a if and only
T(f;Zp)
= b + (-l)n+ib * + a for some b s W h ( w l ( X ) ; Z p ) .
Proof:
Let w = wI(X).
groups
We i d e n t i f y
by t h e i r r e s p e c t i v e
maps
W h ( W l ( X ) ; ~ P) are i d e n t i f i e d Suppose
T(f;~p)
be an h - c o b o r d i s m the map F(w)
all r e l e v a n t
(e.g.
by f,).
= b + (-l)n+ib * + a.
in L e m m a
= (fq(w),@(w)),
Whitehead
W h ( W l ( M ) ; ~ P) and
over ~p with ~ ( W , M ; Z p )
constructed
if
i.
Define
Let
(W;M,M')
= b and q:W ÷ M F:W ÷ Xxl by
w h e r e ~ is a U r y s o h n
function.
Then
the d i a g r a m M
)
Xx0
~
Xxl
~
<2 Xxl
F W tJ M' commutes,
f,
(*)
so ~(f';~p)
= T(F;Zp)
+
T(W,M' ;~p)
= T(f;~.p) =
b
+
T(W,M;~p)
(-l)n+ib
*
+
a
+
-
b
T(W,M';Zp) +
(-l)nb
*
by T h e o r e m =
a.
Now s u p p o s e equivalences
over
T(f;Zp)
3.1.4
we have
~p,
a diagram
T(f';~)
= ~(F;~) = ~(f';~p)
= a.
(*) w i t h
f', F h o m o l o g y
Then
+ T(W,M;~p) - T(W,M';~p) 106
+ ~(W,M;Zp)
a + T(W,M;Zp)
=
Lemma
3.
Let
a homology with
a s Wh(W;~p),
equivalence
T(f;~p)
equivalence
+ (-1)n+I~(W,M;Z~) *
= a. over
over
~,
M and
= ( - l ) n + I T ( f ; ~ p ) *.
Proof:
Let + X',
n odd:
the
the
surgery
cobordant
above
matrix over
F:W ~ X'xl
as
is
X manifolds,
if f:M n ÷ X n is a h o m o l o g y
by
n _> 5, then
a matrix
A
aad
define
normal
maps
follows:
matrix
~p c o b o r d a n t form
obstruction
to a h o m o l o g y represents
representing
Hermitian
f0"
(G,~,~)
Ax =
Then
where
n even:
a normal Apply
map
over
f0:M0
we
can
o
I
~ X';
~p since Let B be a
f' is a h o m o l o g y construct
equivalence
a (-i) ( n + l ) / 2 -
with
/
<__~SfZ
.
.
with
su2gery
A to the basis
] .
.
.
.
.
.
.
.
.
i<~') -1
[o F be
normal
0 in L ~ ( w , W ; Z p ) .
T(f';~p), to
of some
equivalence
A
Let
there
f:M n ÷ X n, M and
X manifolds,
a be r e p r e s e n t e d
Then
The m a t r i x
represents f0 is
~,
C onversely~
T(f;~p)
f':M'
a = ( - l ) n + l a *.
obstruction
of the
107
standard
o/
(G,X,~). kernel
to get
a (-l)n/2-Hermitian this f':M'
form.
Then
÷ X' w i t h
Then
let
cobordant
torsion
f' + ~F:M'
To show h-cobordisms
a simple
f0 is
(G,I,~);
f0:M0
÷ X' r e a l i z e
to a h o m o l o g y
represented
by B.
equivalence
Let
F represent
in L ~ + I ( ~ , W ; ~ ) .
(B~)-
T(W,M;Zp)
form
the
over
+ SW ÷ X' + $(X'xI)
converse,
~p,
(W;M,M')
= a, T ( Y , X ; ~ p ) Poincare
construction
and
= -a.
complex
W
of
suppose
and
Y.
T(f;~p)
(Y;X,X'),
Then
the
~p.
This
over
has
Using
this
= a.
a.
Construct
with
space
we
torsion
N = W
follows
<-7 Y is f
from
the
get
(-l)na * = T(W,M';~p) = T(N,M';~p) =
(-I)nT(N,X,;z2>*
=
(-I)nT(y,x';Zp)*
=
(_l)n((-l)n+la*)*
-
a
by
repeated
use
of T h e o r e m
3.1.4.
We
can n o w
prove
our m a i n
theorem.
Theorem where
i.
Let
A C B C Wh(~;~p)
* is d e f i n e d
by w : ~ ÷
be
{+i}.
self-dual Then
there
subgroups is a long
exact
sequence • .. ÷ H n + I ( ~ / 2 Z ; B / A ) ÷ termin&tin~ Here
L~(~,W;~p)
÷
L~(~,w;~)
÷
Hn(~/2~;B/A)÷
,at H S ( ~ / 2 Z ; B / A ) .
H*(~/2Z;B/A)
denotes
cohomology
108
of g r o u p s ,
[A26].
...
Proof:
We show that
= Hn+I(~/2~;B/A)-" where
~n(I;K,H')
K = (w,W,~p,A), H' = ( w , w , ~ , B ) .
The result will then follow
from Theorem 6.1.2. {b s B: b = (-l)n+ib *} {b+(-l)n+Ib*:beB} + A
Recall that Hn+I(z/2Z;B/A) and define ÷ Hn+I(~/2Z;B/A)
¢: ~ n
by
[f:M ÷ X] = T(f;Zp). ¢ is well-defined and injective by Lemma 2.
(Note we need only consider cobordisms
F:W ÷ Xxl by the remarks
following Corollary 5.2.1, Theorem 6.1.2 and the five lemma.) ¢ is surjective by Lemma 3. We interpret L2kB ~ H 2k sends
the maps in the sequence as follows:
[G,l,p] to [Al];
H2k ÷ L2k_l A sends
[Q] to the class of [~
(9,)-I ;
B ÷ H2k-I L2k_l sends
[~] to [T(~;Zp)];
H2k-i ÷ L2k_2 A sends
[Q] to the (-l)k-l-Hermitian
form defined
by applying Q to the basis of the standard kernel.
6.3.
The Periodicitz Theorem~
Part II.
In this section we use the Rothenberg sequence to complete the periodicity
theorem.
109
T h e o r e m I.
For m > 5,
x@p2:L~(~,w;R)^
+
LA (~,w;R) m+4
is
an isomorphism.
Proof:
By T h e o r e m 6.2.1 and the five lemma we need only
show that
x{P 2 induces
Hm+4(Z/2Z;B/A), as in Section
an i s o m o r p h i s m Hm(~/2Z;B/A)
where we interpret
these groups g e o m e t r i c a l l y
6.2.
Let f:M ~ X be a h o m o l o g y
equivalence
C, the chain complex of f as in Chapter 2. cell d e c o m p o s i t i o n
e0~e2~e
But Hm(~/2~;B/A)
i.
is 2-torsion,
For m > 5,
over R and
Since
{p2 has a
4, the chain complex of
fxl~p 2 is given by C, + C,+ 2 + C,+ 4.
Corollary
÷
Thus T(fxl;~p)
= 3T(f;~).
so this is an isomorphism.
x~p2:~m(g;H,H')
~
~ m + 4 ( g ; H , H ')
is an isomorphism.
6.4.
Simple L i n k i n g Numbers.
Let ~ be a finite group and w:~ ~ {+I) a homomorphism. Let K(~)
denote the k e r n e l of the map Wh(~) ÷ Wh(~,~).
this section we will define a K - t h e o r e t i c linking
forms which
LK(~)(~,w) n
determines
÷ LS(~,w;~) n
In
group of simple
the kernel of
for n odd.
110
This also estimates
the
the kernel of the c o r r e s p o n d i n g
map with K(w)
Let G be a free and b a s e d ~ - m o d u l e Hermitian
a simple
and ~ a (-I) k-
form on G which is n o n - d e g e n e r a t e ,
is injective.
replaced by s.
i.e. AI:G ÷
We further assume that A ~ ® I : G ® ~
isomorphism.
Let A denote ~ / X ~ ;
~
G*
G * ® ~ is
let
Ik :
L e m m a I.
We can associate (i)
X0:KxK ÷ A is ( - l ) k - H e r m i t i a n
(iii)
and non-singular,
~0:K ÷ ~w/l k is an a s s o c i a t e d
Let K -- coker(A~);
rG* C Im A~.
(K,k0,~ 0) where
K is a torsion group,
(ii)
Proof;
to (G,~) a trip!e
Define
~$(x,y)
quadratic
form.
then there exists r so that
A S:G*xG*
÷ ~w by
= 12~(A~irx,A~Iry).
For x,y s Im A~,
(A Ix,
=
=
A ly)
x(A~IF)
£ Z~,
s o t h e map ~o:KXK ÷ A, k o ( f ( x ) , f ( y ) ) f:G* ÷ K, is w e l l - d e f i n e d .
= k$(x,y)
It is easily
rood ~ ,
verified
that
~0
is (-i) k-Hermitian. A p p l y i n g Homz~( 0
+
G
÷
,Zw) to the sequence G*
~
K
÷
0
we get 0 = ExtI(G*,Z~) Therefore
÷
coker(A~)
Extl(K,~w)
+ G*
÷ G**
÷ Hom(K,~w)
= 0.
-~ Extl(K,~w).
Applying Hom~(K,
) to
0
111
+ ~w
÷ Qw
÷ A
÷ 0 gives
0
÷ K*
÷ Hom(K,Q~)
and so Hom(K,Qz) Since
÷ Hom(K,A)
÷ Extl(K,Zw)
÷
Extl(K,~w)
= 0
m ExtI(K,Z~).
A1 = A~¢
, ¢:G
~
G**,
¢(g)(x)
= x(g)*, we have
K = coker(Al)
= coke~(A~) = ooker(A~) Hom(K,A). I0
This map
K ~ Hom(K,A)
is equal to
Ak0 , so
is non-slngular. Define
D0:K ÷
£w]I k by D0(f(x))
='~$(x,x)
mod I k.
We leave it to the reader to show that p 0 is well-defined, D0(xa)
= a*D0(x)a , and ~0(x,y)
D0(x+y)
- P0(x)
+ (-l)kl0(x,y) * =
- p0(y).
(K,10,D 0) is called a standard
If (K,X0,P0) D0:K
is a triple,
÷ ~ / I k an associated
(K,10,D 0) is a simple (i)
and based
e
~
form,
form.
A (-l)k-Hermitian, then we say
form if
(K,-IO,-D0)
is an injective
so that f ~ l : F l ~
linkin$
10:KxK
quadratic
linking
(K,10,D0)
(ii) there
simple
~
is standard,
map f:F I ÷ F2, FI, F 2 free
F2®~
is a simple
isomorphism
and K = coker(f). Define
the group
to be the monoid standard
simple Let
homomorphism
of simple linking
linking
linkin@
of Theorem
rational
~ 2 Sk _ l (W~W) ,
the monoid
of
forms.
6.1.2,
Then coker(~,) homology
forms,
forms modulo
~,:L~k(~,w;Q ) + ~ 2 k _ I ( I ; H , H ' )
H' = (~,w,Q,0). simple
of s i m p l e
where
denote
H = (~,w,~jK(~)),
is the cobordism
equivalences 112
the boundary
modulo
group
cobordism
of tca
homology
over
cobordism).
normal
Lemma
equivalence
2,.
Let
M a manifold
Then
The
exact ~
ExtI(K;Z~),
Kk(M;A)
and we
0
a map
(k-l)-
numbers
associated
define
quadratic
~
~
~ {~
~
A ÷
÷ Kk_l(M;{~)
As
in L e m m a
0 yields
= 0.
Let
I, H o m ( K ; A )
=
get ---* K k - I ( M ; A )
K
÷ Hom(K,A)
÷ Kk(M)
= K*
÷ 0.
and so a n o n - s i n g u l a r
map
~ A.
~ K be
disjointly in M.
represented in M;
Then
we
can d e f i n e
by
(k-l)-spheres
rx = 0 for some
X0(x,y)
=
pairing.
Similarly
satisfies
the p r o p e r t i e s
The
of o u r m a i n
first
i.
a homolosy linkin~
0
= Kk(M).
÷ Hom(K;A)
defines
Theorem
f is
" s e l f - l i n k ins"
÷ Kk_I(M)
Geometrically, x,y
equivalence,
Assume
on K k _ I ( M ) , w i t h
sequence
K = K k _ I ( M ) ; t h e n K*
~0:KxK
and
~ coker(~,).
homology
> 5.
(by any
A.
0 = Kk(M;£~)
This
2k-i
"linking" form
in K(~)
show ~ 2 k _ l ( ~ , w )
f : M ~ X be a r a t i o n a l
a (-l)k-Hermitian
Proof:
torsion s
We w i l l
of d i m e n s i o n
connected.
f.orm~ o v e r
~ with
Let
for
technical
f : M + X be
equivalence
form
on K k _ I ( M )
over
Sx~
where
follows: Sy
~ is
It is e a s i l y
alluded
as
let
embedded
r so rS x b o u n d s
~(Sy,~), U 0.
this
the
a k-chain intersection
checked
that
this
to above.
results
as above. ~ with
Then
torsion
is s t a n d a r d .
113
is:
f is c o b o r d a n t in K(~)
i ff the
to
Proof:
Suppose
homology
F:N + Xxl is a c o b o r d i s m from f to the K(w)
equivalence
k-connected
over Z~ f':M'
and the exact
÷ X.
sequence
We may assume F is
of the pair ~,M)
reduces
to 0
÷ Kk(M)
÷ Kk(N)
÷ Kk(N,M)
By adding trivial handles
~ Kk_I(M)
÷
we can assume Kk(N)
are free and of the same rank,
since Ki(M)
0.
and Kk(N~M)
is a torsion
group,
i = k-l, k. Furthermore,
Kk(N,M)
and so the middle map above
~ Kk(N,3N) defines
This is defined g e o m e t r i c a l l y simple i s o m o r p h i s m the linking
over ~w.
form on Kk_I(M)
Conversely,
0 where
basis
a pairing
in Section
X on Kk(N).
4.3 and A X is a
and so Kk_I(M)
induces
is standard.
assume we have an exact sequence
÷ G
~ G*
the form on Kk_I(M).
~ Kk_I(M) form,
~ 0
simple
over ~ ,
which
Let el,...,e m be a p r e f e r e d
for G and e~,...,e*m the dual basis. Write Ax(e i) = e~aji , aji ~ ~ .
so if Sj is an e m b e d d e d Sjaji
~ Kk(N)* ,
The form on Kk(N)/Kk(M)
I is an ( - l ) k - H e r m i t i a n
induces
~ Kk(N)
is a b o u n d a r y
(k-l)-sphere
in M, say
Then ~(e~aji)
which represents
~i
= Sjaji"
at the S i in Mxl to get (N;M,M').
We have
n i is the core of the handle lifts to the class fi a Kk(N)
at S i.
114
~(e~),
Attach handles 3n i = -Si, where
It follows
represented
= 0,
that Ax(e i)
by qjaji + ~i'
Here we are using Kk(N)
÷ Kk(N,M )
÷ Kk_l(M)
÷ 0
G ~ Kk(N,M') , G* ~ Kk(N,M) ~ K k ( N , M ' ) . Let ~p denote the result of moving qp a small distance so that qp and ~p are disjoint. epbpi, bpi = ~(~p~qjaji
=
Then the image of fi in G is
+ ~i )
-A(Sp,6i).
Let r be an integer with r~ = 0.
Then rS i = ~E i
for some k-chain E i and r~ i - Ejaji is a cycle. rbpi = r~(Sp
Therefore
,~i )
= ~(Sp,Ej aji) =G.a..
P3 Jl where Gpj = ~(Sp,Zj). Choose Kpj SO that re~ = A~(epKpj); construction,
~0(¢(e~),¢(e~))
i also equals ~Kpj.
by the geometric
= rl-~pj and by hypothesis,
Let Pij = ~(Kij i -- ~ij )" and subject the
spheres S.Z to simultaneous mutual intersections
disjoint
regular homotopies
~jaji + ~i; then the image of ~
i
Let ~i ~ Kk(N)
in G = Kk(N,M)
epSpi , where ~pi = bpi + Ppjaji I )aj = bpi + ~(Kpj - ~pj i .aj r pJ i"
= ~K ^
Thus AA(epbpi)
with
Pij to get embedded spheres Si"
Do surgery on the Si to get (N;M,~). represent
it
I
= Ax(r--epKpjaji)
= e~, and so the diagram
115
is
Q*
K
¢
K kc''N,M
Kk( M)~
"
17/ Kk(1~'~ ) ~ G
~
Kk-1(lgI)
commutes. Since i, @ ~, is onto i,A~ = m,, i, is onto. duality.
Since
(aji)
f:M + X has torsion
In the non-simple and our proof
(by Mayer-Vietoris)
Thus Kk_I(M) is e l e m e n t a r y
in K(~).
This
follows
= 0 and Kk(~)
= 0 by
over ~w, as is (<ji), concludes
case s this result
and
the proof.
is due to Wall
[HI8]
his.
We now prove our form of Connolly's r e a l i z a l i z a t i o n theorem
[K6].
Theorem
2.
Let
(K,A0,~ 0) be a simple
a m a n i f o l d with Wl(X) map
F:(W;~_W,~+W) i)
form,
X 2k-2
Then there is a normal
÷ (Xxl;Xx0U~XxI,Xxl)
so that
FI~ W is the identity,
ii) ~orsion
=w, k _> 3.
linking
FI~+W is a homolo6y
in K(~)~ (iii)
equivalence
over ~ with
and
the !inkin~ form on Kk_I(W)
the form on K. 116
coincides
with
Proof:
Let
GI,
exact
sequence
G 2 be free Z w - m o d u l e s
f 0 where and
÷ GI
~ K
a normal
map
This and
k to Xxl
~.
Let
el,...,em,
G 2 respectively.
Add m
to get
N and
a manifold
÷ Xxl.
Then Kk_I(~+N) x. = i - t h 3. Yi = i - t h
over
for G I and
of i n d e x
N
an
÷ 0,
isomorphism
el,...,e*m be b a s e s handles
we have
¢ ~ G2
f is a s i m p l e
trivial
so that
is a free Z w - m o d u l e
sphere
IxS k-I
sphere
sk-lxl
with
generators
i = l,...,m.
gives
Kk_I(~+N)
the
structure
of a s t a n d a r d
kernel,
so m
m
~( i=l [ xiai+Yib i) Here
p denotes Write
with
the
=
usual
f(e i)._
self-intersection
= e~a.. as b e f o r e j jz
a.. in the j - i - t h jm
0 otherwise.
[ b.*a.. z
i=l i
spot
if the
By h y p o t h e s i s ,
cij
e X0(¢(e~),¢(e~))
the
entries
of B are
bij
= cihahj
and
and
above
let A be the m a t r i x equation
A is e l e m e n t a r y
let
in ~ ,
number.
C = (cij);
since
= k0(~(e~),¢(e~)ahj)
over
define
for some
holds Q~.
B =CA.
and Choose Then
h,
m o d Z~
= k0(¢(e~),¢f(eh))
Also, and
=
XO(¢(e~),O)
=
O°
(A'B)*
= B*A
the d i a g o n a l
= A*C*A
terms
of
= (-1)kA*B, A*B
are
117
in
since Ik
C* = (-1)kc,
since
0 = po(@f(ei)) = PO(¢(e~aji)) = It follows
a~.jmcjj..aji mod I k-
that there is a matrix Q over Zw so that
A*B = Q + (-l)kQ *. m Let u i -- j=lT"(xjbji+yjaji) l(ui,u j) = 0, i#j,
in K k_l(~+N).
and so we can do surgery on embedded
spheres representing the classes u.. ! the surgeries
f >~l
0
~
>Ck(W,X)
> ~G2
G2
+ C k_I(W,X),
8g~(Dkx0) K
P
>Ck_l(W,X)
+ Ck(W,X) , e i ~-. g~(Dkx0)
extends gi:sk-lxD k
above).
Then
¢
where the vertical isomorphisms GI
Let W be the trace of
(including the initial surgeries
0
Then ~(u i) = 0
~k!=
> K _z(W)
= yjaji = f(ei).
~ 0
are given by
where g~:(Dk,sk-l)xD k-I
÷ ~+N which represents
e.*l~'~ Yi"
)0
+ (N,)+N)
ui, and
The diagram commutes
since
Thus we have an isomorphism
÷ Kk_I(W). Le5 I$, ~6 denote the linking and self-linking
on Kk_I(W).
We must show l$(p(yi),p(yj))
so that r~ = 0.
= cij.
Choose r
Then rG 2 C f(Gl), so
m re~ = f( 7 e.a!.) iL 1 m lj for some a!. mj £ K~.
ryj
Let A' = (a!.); then AA' = rl and lj
m [ g~(Dkx0) a! .
=
i=l
i~
m
= i[lgi(sk-lx0)aLj. 118
forms
So
l = yl(yi,
l~(p(yi),P(yj))
m [ g~(sk-lx0)a' .) h= I ,, hJ
i m ,gh(Sk_ix0 r h=~ I ~(Yi ' ) ) ahj m m i = r hX 1 qX1 ( l(Yi'Yq)aqh+l(Yi'Xq)bqh)ahi m _ i ~ ~i b a' - ~ h ih hj
= cij m6d ~
since ~BA'r = BA'(AA')-I = BA
= CA 2 and A 2 = al for some a ~ ~. self-linking
numbers.
fact that ~:Ck(W,X)
A similar
Part(ii)
~
follows
Ck_I(W,X)
result holds
for
immediately
has matrix
A.
from the
This
completes
the proof.
Our main theorem
is:
Theorem
3•
coker(~,)
Proof:
The constructions
Lk:coker(3,) jective
÷
~s
by Theorem
~ ~ s2 k _ l ( ~ w ) •
2k-I
in Lemma
(~,w) which
2 define
a map
is w e l l - d e f i n e d
i and surjective
by Theorem
and in-
2.
The only
thing we need to check is that the form on Kk_I(M) linking
form.
Assume
(M,~ M) has a handle k and k-i only.
M is a triple decomposition
The sequence 119
(M;3 M,3+M); with handles
is a
then in dimensions
0 satisfies
+ Ck(M,~_M)
÷
Kk_I(M)
÷
0
(ii) of the definiton.
To see that is standard,
notice
M + (-M) and apply
Corollary
~ Ck_I(M,~_M)
i.
(Kk_I(M),I0,~ 0) @
(Kk_I(M),-10,-~ 0)
that this is the linking Theorem
form of
i.
For w a finite group,
k > 3, there
is an
exact sequence 0
Proof:
÷ ~ S
2k_l(~,w)
Immediate
Corollary
2.
÷
-2k-l" ~,w)
L2k-l( ~,w;~).
from T h e o r e m 6.1.2 and T h e o r e m
As in Corollary
H2k(~/2~;K(~))
÷
ker(
We have the following
3.
i~ there is an exact sequence s ~,w) L2k_l(
s
Proof:
s
+
s ~ L2k_l(W,w;~))
H2k-l(
diagram
120
÷
H2k(l/2~;K(w)
jjjjl
) i[l],
0
)ker(i[l],) I
s - l(Z,w) ) L2k
2k_l(~,w)
(~,w;{)
¢
l
O___~s
s
> L2k_l
K(~), ~ L2k_l(~,w)
s
> L2k_l(~
,w;£)
"~ H2k-l(~/2Z;K(~) )
with exact rows and columns.
It is easy to construct
maps i n d i c a t e d by the dotted resulting
Remark:
sequence
According
the
lines and to show that the
is exact.
to Bass
[C2], T h e o r e m 7.5, if ~ is finite,
then there is an exact sequence
0 ~ SKl(~) It follows
÷ Kl(~W)
~ KI(Q~).
that
K(~) ~ SKI(Z~)/~ for ~ abelian, general
* Chapter
case
and this allows
(theoretically
us to compute K(w)
anyway).
XI.
121
in the
Appendix
A.
Torsion
for n-ads.
In Chapter
5, the torsion of a h o m o l o g y
over a ring of n-ads was
(implicitly)
of the map of u n d e r l y i n g
spaces.
without
A
a c{l,...,n},
that
is a
A A-homomorphism of rank
for
8 c a.
is d e f i n e d
are defined
Define
Kl(A)
of a (finite)
If
of
of the form
is an object
M
so
An(m)
l i n e a ~ group
of
The free
= A(m) n.
GL(n,A)
to be
An; the e l e m e n t a r F t r a n s f o r m a t i o n s Stably,
E(A) = [GL(A),GL(A)].
= GL(A)/E(A).
w by
is e q u i v a l e n t
simple h o m o t o p y
is a group of type (R~)(a) = Rw(a).
GL(1,~p~) f(m)(k)
Define the W h i t e h e a d
to the d e f i n i t i o n
tree, used by Farrell
the theory of infinite
subgroup
for each
in the obvious way.
as before.
This d e f i n i t i o n
R~
i e
and all maps are compatible.
n, An, is d e f i n e d by
E(n,A)
define
2n
A A-module
A(~)-module
the group of a u t o m o r p h l s m s
K1
this
is a ring and h o m o m o r p h i s m s
Define the 5eneral
of
We can g e n e r a l i z e
be a ring of type
A(~)
÷ A(a)
M(m)
A-module
d e f i n e d to be the t o r s i o n
too m u c h trouble. Let
ras:A(8)
equivalence
generated
= rgk,
types.
2n
If
group by
122
and
See R
R = ~p, let
by maps
ke~pW(a),
and W a g o n e r
[Dll].
is a
ring,
U
be the
f:~pW ÷ ~p~ geT(m),
in
r~.
=
Let be m a n i f o l d
M = (IMI;M1,
n-ads.
We say that
if there is an n-ad is a m a n i f o l d M CINI each
and ~,
Theorem then
i.
M' c INI
If
N
N ~ M x !
T(N,M)
induction.
are homotopy
M'
between
1' , . . . , M ' n _ l
are h - c o b o r d a n t so that
INI
Nn_l U M',
equivalences,
is an h - c o b o r d i s m
M(~)
between
M
and for and
M'(~).
and
M'
if and only if a t o r s i o n invariant vanishes.
is d e f i n e d to be the t o r s i o n of the
"chain complex n-ad" KI(~I(M))
and
MuN I m...o
is an h - c o b o r d i s m
• (N,M) e Wh(Wl(M)) Proof:
M
M' = ( I M ' I ; M
and
N : (INI;NI,...,Nn_I)
with b o u n d a r y
N(~)
. . . ,M n _ l )
C,(N,M)(~)
= C,(N(~),M(~))
, where the c o n t r a c t i o n The result
follows
$
is c o n s t r u c t e d
by the s - c o b o r d l s m
and induction.
123
in by
theorem
)
Appendix
B.
Higher
L-Theories.
In Chapter by geometric
5, we defined
construction.
is there an algebraic Chapter answer
is yes for
K
Ignoring denote
Ln(K(~,I)
Case i.
The following
definition
4 that the answer
of
is yes if
torsion
K
We saw in
is a space.
The
and orientation,
let
Lm(W÷w'; % )
÷ K(~',l);%).
4-tuples
(i) (ii)
K
%w
with subkernel (ii)
sl~
is a subkernel
of
~ (G' I' ~' K')
(G,k,~)
in Chapter
7.
where:
S
G ® ~ w P if there
-ff
form over %w'. is a kernel
so that
@ H @ (G',-I',-~')
= HI
is a kernel
SI, and any automorphism
= =.~'~
to
Ke
of
(s~
P
modulo
HI ® % w
~
<~')
Z~p~'
® ~'
taking
is in
EU(~pW').
p
L2k+l(W+w';%)
(G,X,~,K)
[Mig]
is a (-l)k-Hermitian
with subkernel
(i)
by Wall
(G,I,~,K)
(G,k,~)
(G,k,~,K)
over
Then
Ln(K;R)?
arises:
n = 2k+l.
We consider
H
question
groups
a 2-ad and we sketch the construction.
This is done in detail
Define
surgery o b s t r u c t i o n
is isomorphic
the equivalence
to the group of objects
relation
124
~.
Case 2.
n
2k.
=
This was determined Wall
[H19],
where
¢
W
Chapters
= <~,w'>. Define
xlj,
(see the end of Section
1.7).
module
of dimension X
r)
~pW'
the relation
I + (-l)kQx = A £ SL(r,ZZpw')
(ll)
P' - P = X + (-l)kx * + X*QX
+
~ (P',Q')
by
map
h:St(~p~')
= St U(~p~')/h(ker
the associated
(P,Q)
Q = AQ'A*.
st
St U(~pW')'
(on a free
so that
and we have a natural
split group,
Ur(~p~)
i1
forms over
modulo
and
to be the group of pairs
(1)
(iii) Define
by
St Ur(~pW')
(-l)k-symmetrlc
see also
W h 2 ( w ' ; ~ p) = K2(~p~')/ker
xijxji
of
is an
Let
[HI4];
St(Z~p~') ÷ E(~p~'),
generated
(P,Q)
if there
8 and 17G.
is the natural map
is the subgroup ET'
by Sharpe
¢IW),
+ St U(~p~'). where
~
Let
denotes
e.~.,
is the set of things
a + (-l)k+la * = ~*y,
125
,
,
b + (-l)k+ib * = ~*B.
¢IW,
T'
acts on
St
Let
St U ( % ~ ' ) '
U(~';~p)
P(~+wT;~p)
by conjugation and define
= T'XT,St U ( ~ p W ' ) ' / [ w ' , w ' ] .
be the p u l l - b a c k of
u(zp~) $ st Finally,
+
we have
L2k(W+w';%) ~ P(~÷~';%)/. Considerations like these can be used to give algebraic definitions of surgery groups to solve problems of the form "how to get a homology equivalence over Int(M)
and a homology equivalence over
R'
on
R
~M".
on This
is similar to the problems solved by Cappell and Shaneson's relative (with
F-groups,
2 ~P)
The condition
[KS].
Miscenko
([K8])
defines
L
groups
algebraically by an algebraic bordism procedure. 2 6P
(which eliminates self-intersection
problems) has been removed
(at least in some cases) by
Connolly.
126
Append.ix C.
L
Groups of Free Abelian
Groups.
n
In this
section
is i d e n t i c a l
to that
reader
for details.
there
T h e o r e m 1.
Proof:
every
map.
element
normal
map
Let
in ¢
(smooth)
of
exact
K
x ~,w;~)
then we get a c o m m u t a t i v e
is
Wl(K)
fI3X:~X
(L,3L)
of
: f-l(,)
0.
= G.
Then
by a
4.3.2.
* S 1. SI
÷
the
X ÷ K x I x SI ÷ S1
the b a s e p o i n t If
with
the
n ~ 7)
+ Lhn_l(G,W;~p)
by T h e o r e m
and also
M ÷ X ÷ SI
(for
is r e p r e s e n t e d
the c o m p o s i t i o n
so that
The p r o o f
and we refer
÷ Ln S(G x ~,W;~p)
be a m a n i f o l d
f
[H9]
sequence
+ Ln s(G x Z,W;~p)
L s(G n
fibration
by a h o m o t o p y value
a split
M * X ÷ K x I x S1 Assume
Lk(~;~p).
in S h a n e s o n
Ln S(o,w;~)
The map
functorial
given
There is
0 ÷ LnS(G,W;~p)
we compute
is a
Change
¢
is a r e g u l a r (N,3N)
= (f~)-l(,)
diagram
(N,~N)
÷
(L,~L)
(M,~M)
÷
(X,~X)
Sl . Clearly
~IN
is a normal
sequence
of a f i b r a t i o n
map and by a p p l y i n g
to the
fibratlons
127
the h o m o t o p y
above,
¢]~N:~N
~ ~L
is a homology equivalence over LnS(G x ~,W;~p) ~ Lhn_l(G,W;~p) of
¢18N.
Ln s
¢
This is a well-deflned homomorphism,
splitting is defined by to
~ . Define P by sending
to the class and the
xS l, as in Section 5.3.
This goes
by Kwun and Sczcarba [D16]. The next theorem allows us to apply this.
Theorem 2.
Let
group.
Then
Proof:
Assume
G
be a finitely generated free abelian
Wh(G;~p) = 0. G = ~.
Then
~p[G] ~ 2~p[t,t -1] , the ring of
Laurant polynomials over
E . According to Bass [C2], Chapter P XII, Theorem 7.4, there is an exact sequence Kl(2~p[t]) @ Kl(2~p[t-l]) ÷ Kl(Z~p[t,t-1])
*
K0(2~p)
+
But Kl(%[t,t-l]) Kl(~p[t]) and similarly for Thus
~
t -1.
Kl(%[t,t-l])/~
result follows.
Kl(~p) = ~Zp
-= K0(~ ~) ~ ~, and the
The general case follows by induction and
the fact
~p[G × ~] ~ ~p[G][t,t-l].
Corollary
i.
n
Ln(~k;~zp) -= @ L n _ i ( l ; ~ p ) . i=O
128
0
Appendix
Ambient
D.
Sursery
and Surgery
Leaving
a Sub m a n i f o l d
~ixed.
In this For
simplicity,
involke
the
problems
section
we will
considered.
Poincare
the general
g
is a simple ambient
because
so we can
of t r a n s v e r s a l i t y
only m a n i f o l d s
will
be
of t r a n s v e r s a l i t y
can be made
to get
be a simple
homotopic homotopy
to
n.
go
homotopy
If
X
so that
equivalence?
equivalence
is a s u b m a n i f o l d g01g0-1X:g0-1X
This
is the p r o b l e m
+ X of
surgery.
regular
F
Theorem
a simple
X
I.
g
There
obstruction
of
be a c o b o r d l s m
of
k > 5
X
in
Y.
is t r a n s v e r s e
to
X
neighborhood
of
so that
equivalence
~ = 0. (F,~F) ÷
Then
if
to a simple
in
~ = 0
129
be a
M = g-lx;
c ( g l M ) E L k s (Wl X;~)' g01g0-1X
and
0 ~ e.
that
the
vanishes.
homotopy
E
N.
g ~ go' with
it follows
(E,~E)
and let
and put
M
are two o b s t r u c t i o n s
+ WlY;~)
homotopy
Suppose
has d i m e n s i o n
neighborhood
be a r e g u l a r
ecLnS(Wl(Y-X)
Proof:
A = 0
for a d i s c u s s i o n
of d i m e n s i o n
Assume let
Also,
modifications
g:N ÷ Y
Suppose closed
[E12]
and
on submanifolds.
case.
manifolds
Y, is
P = ~
complexes,
Suitable
Suppose
of
some r e s u l t s
theorem.
(see Jones
obstructions.)
between
assume
s-cobordism
with
we give
Let
equivalence.
÷ X
surgery
f:(P,Q) Form
~
(E,~E)
the n o r m a l
map
@:N
defined
by
g
obstruction R
is the
Let
8
I:N
x
right
be the
I + Y
x
to d o i n g
x I <J P + Y x I
surgery
boundary
and
f:P ÷ E.
relative
of
set of all
I
x
P,
such
(P,Q).
lies
to in
0 6 e, t h e n
homotopy
equivalence
leaving
N × 0
W ~ N x I.
between
0 ~JR,
where
LnS(Zl(Y-X) for all
+ ~lY). cobordisms
-1
g'.
to
gives
X. Assume
F'(x,t) g-l(x
the
the
see t h i s ,
Let
F:N
F':N
and
÷
By the
to a s i m p l e
(Y x !;Y
x O,Y
s-cobordism
x i),
theorem,
result.
obstruction suppose
x I + Y
Then
g,-l(x
g = g'
ambient and
g'
and
x I) so the
is
between
is t r a n s v e r s e
F'-I(x
x i),
130
to the
be a h o m o t o p y
x I + Y x I
= (F(x,t),t). x 0)
is c o b o r d a n t
fixed.
gives
To
¢
~':(W;~_W,~+W) R
also
problem.
transverse
where
and
Thls
This
and
the
R
If
g
x
obstructions
N xM i
surgery
N
Then
to
X x I,
is a c o b o r d i s m obstructions
(which
are
cobordism
obstructions transverse
are i n d e p e n d e n t
to
wI(Y-X)
by T h e o r e m
~ ~i Y, e.g.,
A more and Shaneson knot
theory.
[G2].
are the
of which
same.
Thus
way we make
the
g
X.
Note if
invariants)
careful
5.1.1, if
Ln
(wI(Y-X)
~ WlY)
= 0
n-k ~ 3.
analysis
has been made
[K5]
in the
codimenslon
The
simply
connected
Se also Lopez
S
de M e d r a n o
2 case
case
[J22],
by Cappell
and applied
to
is due to B r o w d e r sections
111.3.2
and V!. 3.
A similar [A21]
can be used
As before, i.e.,
this
procedure,
to do
is e s s e n t i a l l y
we look only First
an example.
2 or
is a finite ~.
Let
By T h e o r e m
el,...,e r
4.3.2,
¢i:(Wi;~_Wi,3+Wi) the n-torus.
Wi
Let
Define
0 problem,
a homomorphism by A p p e n d i x groups
of
Ln+l(~n).
by
(T n x I;T n x 0,T n x i) p(e i) = the
C,
of order
be a set of g e n e r a t o r s ei
fixed.
neighborhoods.
sum of cyclic
represent ~
a submanifold
a codimension
as follows:
direct
by an idea of Wall
leaving
at the r e g u l a r
P : L n + l ( ~ n) ÷ L n + l ( ~ n-l) Lm(~)
surgery
modified
surgery
obstruction
D 2 x T n-I ~ T n x I k J D 2 x T n-I
wi
131
where
Tn
is
of
x 0 ~ D 2 x T n-I
Since
L n + l ( ~ n)
non-zero map has
element
in
W ÷ Tn x I surgery
leaving
to a s i m p l e N
so that
D 2 x T n-I
homotopy
is r e p r e s e n t e d
Thus
we
cannot
be a n o r m a l
map,
do
a
by a
surgery
n > 5.
where
Suppose
equivalence
and that
k
¢IM:M
so that
N
¢ M
and
Y
is c o b o r d a n t is s u b m a n i f o l d
+ X
is a s i m p l e
equivalence.
2.
There
so that
if
0 ~ e, t h e n
(i)
is c o b o r d a n t
to
is a s i m p l e h o m o t o p y
¢+:N+
÷ Y
with
equivalence.
¢+IM = } I M .
Let
~:Q ÷ Y
homotopy to
be a c o b o r d i s m
equivalence X
and
cobordism
between
Let
be r e g u l a r
D,E
¢
÷ Wl(Y);~)
M = @+-Ix
(iii)
transverse
8 C LnS(Wl(Y-X)
is an o b s t r u c t i o n
~+
(ii)
slmple
exists
W ~ D 2 x T n-I + T n x I k 3 D 2 x T n-I
of d i m e n s i o n
Theorem
Proof:
there
fixed.
of d i m e n s i o n
homotopy
This
0.
¢:N + Y
are m a n i f o l d s
@ Ln(~n-l),
ker(p).
obstruction
Let
of
~ L n + l ( ~ n-l)
let
¢IM:M
¢+:N+
between
+ Y.
Assume
W = ~-l(x). ÷ X
and
neighborhoods
¢
Then
W
¢+IM+:M+
+ X,
of
in
W,X
and ~
a is
is a M+ = ¢+-lx. Q,Y,
respectively. Then and
~
@
is a s i m p l e
It f o l l o w s
that
the
extends
to
homotopy
~:D ~ N+ x I + E x I ~ Y equivalence
obstruction
to d o i n g
132
on ~ _ D ~ ( N + surgery
on
x I,
x i).
rel lies
~_D ~ ( N +
in
LnS(~l(Y-X)
different
homotopy
Since is e o b o r d a n t
by
9',
Then
Now
9'
~l((Y
D
and
and
x !,(Y
homotopy
(E x I ~ Y x I;E
So
A'
x i).
on
Y × I) × I)
9 T'
to get
and
so
P m V x I.
equivalence x I,Y
x I;E)
is an s - c o b o r d i s m
is an s - c o b o r d i s m
Z
x I) x I;
equivalence
is an s - c o b o r d i s m
÷
x I)
× I ~
(E x I,E)
induced
((E x I <]Y
on
÷
U = V x I ~
of t r i a d s
homotopy
surgery
(E x I,E)
between
N+'
between = ~_B'
N+ x i = ~+B' Let
union
B'
Z0) ÷
to a s i m p l e
= V - (A'-C'). and
x 1 U
x I),
(A',C')
Let
map
x 0 uP (E x I)
P
÷
equivalence
× I) x l) ÷ ~ I ( ( E
As b e f o r e ,
C',
9':(A,C)
a normal
assume
A = (¢')-l(E
(E x I,E).
so we can do
is h o m o t o p i c
B'
homotopy
we have
(V;A',B';C')
where
x I),
is a s i m p l e
is an i s o m o r p h i s m ,
Thus
x i).
x I)
~T'
and
(P;P1,P2).
C = (9')-I(E ~ nl(E
to a s i m p l e
× I, and
Let
x 0 ~ A',B
(E x I ~ Y
equivalence
by c o n s i d e r i n g
is c o b o r d a n t
9 0 : ( Z , Z 0) ÷
9T':(U;V
V × 0 ~A',
~
to a s i m p l e
A x i.
8
E x 1 = E.
~I(E)
by a c o b o r d i s m
Define
9':V ÷ E × I uY
to
x I),
homotopy
Q.
equivalence
B = (9,)-l(y
a simple
~ ~lY).
0 6 e, t h e n
is t r a n s v e r s e
along
to get
cobordisms If
9'
i)
x
of
R = N x I ~ A' ~
N x 0, N
+
x I
and
B'.
Then
N" = N x i ~
133
8R ~A'
is the
disjoint
~ N+ x 0.
We can that
extend $ ~
$":P"
~ Y
is c o b o r d a n t
extend
our m a p s
~+
leaving
map
between to
is a c o b o r d i s m
Since to
to a n o r m a l
is a c o b o r d i s m
Since
and
our m a p s
to
~+,
$:R ~ Y.
~ + (-~+) ~"
and
It f o l l o w s ~":N"
is n u l l - c o b o r d a n t ;
bounding
~".
Let
÷ Y. say
T : RUP"
T ÷ Y.
A'
~nd
M
fixed.
B'
are This
products, concludes
134
~ the
is c o b o r d a n t proof.
Appendix E.
Homotopy and Homology Spheres}
In this section we describe the calculation of groups of homotopy or homology spheres over theory of resolutions of Let
(W;M,M')
is an
over
Zp
A closed
We let
classes of
H-manifold
H,(Z;~p) & H,(sn;~p).
H-cobordism over
H,(W,M';Zp) = 0°
This is applied to the
~p-homology manifolds.
H = PL or DIFF.
Zp-homology sphere if
~p.
~(H)
~p
if
zn
A cobordism
H,(W,M;~p) =
denote the group of
H ~p-homology
is a
n-spheres
H-cobordism
(addition given
by connected sum). A
~p-homology sphere
~I(Z) = 0. gp
We let
classes of
method of
8P(H) n
Z
gp-homotopy sphere if
denote the group of h-cobordism over
H gp-homotopy ~-spheres.
Generalizing the
[G20], we have
Theorem t .
Let
n _> 4
and
2 ,~ P .
Define a homomorphism sending
is a
x
to the
r' :L4k(l;~p)/L4k(1)
r:L4k(l;~ P)
8P(H) & ~P(H).
> 8~k_I(PL)
by
~p-homotopy sphere bounding the manifold
obtained by plumbing with guments show that
Then
r
x
(see Section 4.4).
defines injection > @~k_I(PL) .
iAdded May 1976
135
Surgery ar-
T h e o r e m 2.
For
n > 4, n~3mod (4 )
H
n=4k-1
@ L4k (i; ~p)/L4k w(k)-i
where
Hn
is a finite
of p a r t i t i o n s
of
P-torsion
group and
z(k)
is the number
k.
For the proofs of T h e o r e m s
1 and 2, see
[KI3].
In the smooth case, we have the results of Barge, Latour and Vogel can be d e f i n e d -P ~4k-I
[KI4]:
A left inverse
in the smooth h o m o l o g y
r'
above
sphere case; we let
~p P ~n = ~n (DIFF)
be the kernel of this map,
Then for
to the map
Lannes,
if
n~3mod(4).
n > 4,
~P ~{ ® ~p • ~Q ~n = ~n ~n @ ~(P)
Thus,
the c a l c u l a t i o n s
e n o u g h to c h a r a c t e r i z e In the case bP4k/bP4k
of ~n ~p ~n"
2 { P,
~ ap~/8~ ~
[G20],
it follows
@ WP where peP P '
the group of spheres w h i c h b o u n d One a p p l i c a t i o n manifolds.
Let
~@ ~n
[FI] and
from bP4k <
P 04k_I(DIFF)
%-parailelizable
be a s u r j e c t i v e
136
are
[K2] that
of this is to the study of
f:M .... > N
[KI4]
is the
manifolds.
~p-homology
PL-map between
polyhedra. for e a c h
Theorem Then M
f
is a
(Sullivan)
Let
We
say
~-resolution
if
~ " --'H,[f-l(x);~p) = 0
x e N.
3.
there
is a
if and o n l y
Nn
~-resolution if o b s t r u c t i o n s
be a f:M n • in
137
~p-homology > N
to a
H k ( N ; ~ k-i P (PL))
manifold. PL-manifold vanish.
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153
P.,
INDEX
adJoint 60 Arf invariant 77 Atiyah, M. and MacDonald, I. 24 Ambient surgery 129
Haefliger, A. and Poenaru, V. 12 handle 54 handle subtraction 82 Hasse-Minkowski invariant 76 h-cobordism 38 Hermitian form 60 Hirsch, M. 12 homology equivalence 3 homology intersection pairing 14 homology manifold 40 homology type 3 Hudson, J. 38
Bass, H. 21, 121, 128 Bernstein, I. 74 block bundle 7 Bredon, G. 40 Browder, W. 46, 78, 131 Cappell, S. and Shaneson, J. 28, 84, 104, 126, 131 classifying space for surgery 95 cobordism extension property 104 Cohen, M. 37 colocalization 27 conjugate closed subgroup 41 Connolly, F. 116, 126 deformation 32 degree i 41, 86 dimension (of a Poincare complex) 39 dual (of a module) 1 duality theorem 43 A-map 4 A-set 4 elementary matrix 20 elementary P-collapse, expansion 32 Farrell, F. and Wagoner, J. 122 free and based module 21 free module 1 formal deformation 32 fundamental class 39 Gabriel, P. and Zisman, M. 5 Gauss, C. 75 general linear group 20, 122 geometric realization 5 group ring 2 groupoid of type 2n 92
immersion classification theorem 12 infinite simple homotopy type 122 intersection numbers 14 Jones, L.
129
Kan, D. 5 kernel 60 Kervaire, M. 38 Kerv&ire, M. and Milnor, J. 78 Kervaire manifold 78 Kirby, R. and Siebermann, L. 54 Kwan, K. and Szczarba, R. 128 Lam, T. 75 Lees, J. 12 linking forms, group of ll2 , simple ll2 , standard simple local homotopy (homology) 25 local n-sphere 25 localization, algebraic 23 , geometric 24 , relative 26 Lopez de Medrano, S. 131
112
manifold n-ad 86 microbundle l0 Milnor Poincare complex (manifold) 78 Milnor, J. 5, 7, 10, 17, 22, 28, 29, 54 and Husemoller, D. 76 Miscenko, A. 126 Morse theory 54
154
Symbol Index Ak
Ik
60
16, 60
Imm(M,N) (BG)p
47
BH, BA
5
CHnA(~,w;R)
i01
K0(A)
19
KI(A)
21, 122
KI(A)
21 23
C (n)
85
K2(A)
c,(x)
2
El(),
C,(f),
f
a map
C,(f>,
f
a map of pairs 42, 83
~i,~,6i
42
ii
K(~)
Ki( ) 3 llO
K(~,l), ~ a groupoid of type 2n
LA2k(A)
85
D_k,D+k,~_Dk,3+D k
33
62
LA2k+I(A)
64
Lm(H) , Lm'(~) E(u,A), E(A) EUkA(u,A) Ex
LmA(K;R)
20
87
92
~m(g;H,E ') 103
63
ZS2k_i(~,w)
5
i12
Lmh(K;R), LmS(K;R) GL(u,A), Gp/H
48
Gq(R)
7
GL(A)
A"
1
°~pH(X)
Hn ( Z~/22Z; )
Hq, Hq
20,122
109
for H=TOP, PL, DIFF 6
92
80
Wr(¢), ¢ a map
55
Wr(~), @ a map of pairs Wr(X), X an n-ad H(P)
Qm(~) 155
24
87
86
82
92
Rw
2
xN
R(TM,TN)
~m(n)
103
SKl(A)
Xp
24
Xp
27
41
21 % , Z~(p) 24
85 23
St(n,A),
St(A)
22
63 *
(on R~)
*
(on
TM
I0
TM
8
2
KI(A))
UkA(n,A)
22
63
28
Wh(~;R) Wh2(~;~p)
125
~¢ 94 n cm (n) 87
a~(g)
39
[x,~x]
87
~m(~',n)
Sn, k S-1A
[x]
ii
96
87
156
n-ad 85 normal cobordism 51 invariant 51 map 50, 57
subkernel 61 Sullivan, D. 25, 47, 50, 80 surgery 54 hypothesis 64 leaving a sub-manifold fixed 131 obstruction theorem 64, 93 rel the boundary 55 with coefficients 57 Swan, R. 21
Pardon, W. 104 periodicity isomorphism 96, ii0 plumbing theorem 72 Poincare complex 39 n-ad 86 pair 41 preferred base 21 principal H-bundle 5 A-fibration 5 projective module 1 ~-~ theorem 83
tangent block bundle 8 microbundle I0 Thom space 45 torsion for n-ads 122 of a chain complex 22 of a Hermitian form 60 of a map 29 of a Poincare complex 39 trace 54 transfer 39
Quinn, F. 94, 95 realization theorem 72 ring with involution i Rothenberg, M. 105 Rourke, C. and Sanderson, B. 5, 7, 17, 54
unitary Steinberg group Wall, C.T.C.
s-basis i s-cobordism 38 s-cobordism theorem 38, 123 self-dual 41 self-intersection number 16 Serre, J. 76 s-free 1 Shaneson, J. 96, 105, 127 Sharpe, R. 125 Siebenmann, L. 19 signature 75 simple chain complex 22 equivalence 22 homology equivalence homology type 36 Poincare complex 39 spherical fibration (over a ring) l0 Spanier, E. 22, 30, 97 Spivak, M. 10, 45 Spivak normal fibration 45 split group 125 stable basis i stably free 1 standard plane 60 Steinberg group 23 Stong, R. 94
125
19, 41, 47, 58, 64, 80, 84, 95, 96, 116, 124, 125, 131 Wall group 62, 64, 87, 92, 124, 126 Whitehead, J.H.C. 37 Whitehead group of a group 28 of a ring 21 , secondary 125 Whitehead lemma 20 Whitney lemma 16 Williamson, R. 96 29
157