Semigroup Forum, Vol. 5 (1972), 160-166.
(0,i) - MATRICES AND SEMIGROUP$ OF RING ENDOMORPHISMS Carlton J. Maxson Commun...
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Semigroup Forum, Vol. 5 (1972), 160-166.
(0,i) - MATRICES AND SEMIGROUP$ OF RING ENDOMORPHISMS Carlton J. Maxson Communicated by P. A. Grillet
In this paper we investigate semigroups of ring endomorphisms of several classes of rings. As one result we find that the Green relations in the endomorphism semigroup, End R, for a ring R in a given class, are restrictions of those in the transformation semigroup ' f i R "
i.
Introduction. E. S. Ljapin,
[5], in his discussion of the future
of research in semigroups, makes a considerable point of the importance of studying semigroups of endomorphisms of algebraic structures in order to determine properties of the structures
themselves.
appearance of this statement,
Since the
semigroups of endomor-
phisms of vector spaces have been systematically studied by several mathematicians
(see e.g.
[2]) and
these results show that the theory of semigroups can be successfully applied to the study of endomorphisms vector spaces.
of
Following the suggestion of Ljapin, we 160
9 1972 by Springer-Verlag New York Inc.
MAXSON
investigate the semigroups of ring endomorphisms of certain classes of rings.
2.
Products of Cyclic Rings. We first investigate the semigroup of ring endo-
morphisms of a ring R with identity which is a product n of a finite number of cyclic rings, R = H R i. Recall i=l that a ring R i with identity is cyclic if its additive group is cyclic.
Moreover, R i ~ Z, the ring of integers
or R i is isomorphic to some residue class ring, Zn(i), for some positive integer n(i).
If
~i (i) ~m (i) n(i) = Pl "''Pm where the pj are distinct primes, then Zn(i) is ring isomorphic to ZPll(1). x...x Zpmm~ (i)" Thus R is isomorphic to Z x...x Z
x
Z
(*)
x...
x...x Z PI ll
Pllrlj
ro ...x
Z
x...x Z
Ph ~hl.
,
phc~hrh
where, without loss of generality, we order the factors in such a manner that ~iJ ~ ~ik when j ~ k. Let End R denote the semlgroup of ring endomorphlsms of R and EndlR, the subsemigroup of identity preserving ring endomorphisms.
161
For i # k,
MAXSON
End(Z
, Z ~ ) = {0}. PiiJ Pk ks
L E M M A 2.1.
For i = k we have
Let @ e End(Z
, Z P
).
If ~ < B, ~ = 0
P
> 8 then @ = 0 or e @ = e~ where e multiplicative
identities
of Z
and e~ are the D
and Z P
Also,
respectively. P
if ~ e End(Z e' Z), then ~ -= 0 while P
e End(Z,
if
Z ~) then ~ i s th___eezero map or the m o r p h i s m P
preservin~
identities.
Notation:
Since the above identity preserving
morphisms
If
Z 8 + Z e and Z § Z e are of the form x § x P P P
(rood p~) we use "i" to denote them. THEOREM
2.2.
i s semiKroup
Let R be defined isomorphic
as in (*).
to the collection
Then End R of all r x r
h matrices
(where r =
Z
r i) of the form
i=0 m
#ii
-
(**)
[~iJ]
=
~ir 0
"'"
~ir
~roro
" ..
~ro r
ryo
0
...o
q o...o 0
0 162
0
MAXSON
Each A S i = i, 2 h is square matrix i' ,..., a consisting o f 0's and l's; consequently
[$ij ] can be
considered as a (011)-matrix with at most a single 1 i__n_n each column.
Further EndlR is isomorphic t_~o SI, the
subsemigroup o f S consisting o f iOll)-matrices with exactly one 1 in each column.
3,
Products of rigid rings. A ring K is said to rigid if K 2 # (0) and
End K = {0,i} where 1 denotes the identity map on K. Let R = rigid ring. THEOREM 3.1.
n H R. such that, for every i, R. = K, K a i=l I 1 Similar to Theorem 2.2 we obtain If R = --
n H R., R. = K, K ! rigid ring 1 i i=l
then End R ~ S where S is the semigroup o f n x n column monomial
(011)-matrices and EndlR is isomorphic to the
semi~roup of n x n strictly column monomial (0,1)-matrices. We now turn to a determination of the Green relations on End R where R is a ring as described in the above theorem.
We recall that in ~ X '
the full
transformation semigroup on a set X, the Green relations have been characterized in terms of images and equivalence kernels
([i]).
For any ring T, End T is a subsemigroup of J T " We consider the question:
Are the Green relations in
163
MAXSON
End T restrictions of those in J T " question has a negative answer. the field of rational functions over Z 2.; i.e. T = Z2(x).
In general this
For example,
in one indeterminant
The map s : T § T
determined by ks = k, k E T and xa = x but not surjective. sEnd T # i End T.
2
is injective
This implies Ker s = Ker i but Also,
there exist rings T such that
for s, 8 c End T, Im a = Im 8 but However,
let T be
(End T)a ~ (End T)8.
for products of rigid rings we do obtain
an affirmative answer to our question. T H E O R E M 3.2. rigid ring.
Let R =
n H R. w h e r e each R i = K, K a 1 i=l
For ~, B E End R, let ~ correspond to the
m a t r i x A and B to the m a t r i x B.
The following are
equivalent : (a)
Ker s = Ker B,
(b)
A and B have the same non-zero rows,
(c)
s End R = B End R.
T H E O R E M 3.3. theorem,
as the previous
the following are equivalent:
(a)
Im s = I m
(b)
There exists a p e r m u t a t i o n m a t r i x P such that PA=
(c)
4.
Under the same hypothesis
8.
B.
(End R) s = (End R) 8.
A R e p r e s e n t a t i o n Theorem. Several authors have obtained c h a r a c t e r i z a t i o n s
semigroups as e n d o m o r p h i s m semigroups algebraic structures.
G. Gr~tzer 164
of various
[3] shows that a
of
MAXSON
semigroup
S is isomorphic
of some abstract identity.
to an endomorphism
semigroup
algebra A if, and only if, S has an
Closely related to this is the recent work
of Hedrlin and Lambek any semigroup many monoids
[4] in which they establish:
S with identity,
there exist arbitrarily
(i.e., semigroups with identity)
that S is isomorphic
for
M such
to the semigroup of endomorphisms
of M. In this section we give a partial solution corresponding
problem of rings.
to the
That is, using a
procedure
similar to one used in [I], we show that every
semigroup
S can be represented
semigroup,
as a subsemigroup
End R, of ring endomorphisms
of the
of some ring R.
In fact, R can be chosen in a "nice" way. THEOREM 4.1.
Every semigroup
semigroup of ~
S is isomorphic
to
preserving ring endomorphisms
some Boolean ring. (Sketch of proof.)
Let s E S I and define
M(s) ~ (aij(s)), where
(i, j) e S I x S I by 1, if sj = i,
aij (s) = 0, otherwise. : S § M = {M(s)
I s e S I} is a representation
and M can be considered where R =
as a subsemigroup
~ Re, R~ ~ Z2, seA
[A 1 = IS11.
165
of S
of EndlR
of
MAXSON
REFERENCES
[13
Clifford, A. and Preston, G., Algebraic Theory of Semigroups, Amer. Math. Soc. Surveys, Vols I and II, Providence, 1961 and 1967.
[2]
Gluskin, L., Semigroups and rings o_~_fendomorphisms of linear spaces, I and II. Amer. Math. Soc. Translations, Series 2, 45(1965), 105-145.
[3]
Gr~tzer, G., On the endomorphism semigroup o_~f simple algebras. Math. Annalen 170(1967), 334-338.
[4]
Hedrlin, Z. and Lambek, J., How comprehensive is the category o_~fsemigroups? Journal of Algebra 11(1969), 195-212.
[53
Ljapin, E., Semigroups. Amer. Math. Soc. Translations, Vol 3, Providence, 1963.
Mathematics Department Texas A&M University College Station, Texas
77843
Received April 7, 1972 and in revised form, July 24, 1972.
166