This content was uploaded by our users and we assume good faith they have the permission to share this book. If you own the copyright to this book and it is wrongfully on our website, we offer a simple DMCA procedure to remove your content from our site. Start by pressing the button below!
(the infinite cyclic group generated by p), La(R) = Lp(R) is a simple pli (pri)-domain whenever R is a field and pis an automorphism of R having infinite period (Jacobson [43], p. 38 and Jacobson [64a], p. 2ll). Moreover, in this case, each left (right) ideal of Lp(R) can be generated by an element a E LP(R) having the form a = n
.L 1=0
a 1p1• Since a fixed R and G will be assumed during the
ensuing discussion, we shall replace the symbol La(R) with L. Let MEL-mod, and let R be commutative. Note that if we denote the L action of a on mE M by a(m), we obtain for each a E G, an additive homomorphism of M satisfying a(am) = a(a)a(m) for all a E R. Using these observations, it is quite easy to define an L action on homR(M, N) and M ® RN whenever M, N E L-mod. homR(M, N): for f E homR(M, N), .L aqa E L, q
define
,2 aqaf(m) q
M ® RN: for
=
,2 aqa(f(a- 1 (m)))
Vm EM.
q
.LI m1 ® n 1 E M ®
RN,
.L aqa E L, define q
,2 aqa ,2 m1 ® n 1 = ,2 aq(a(m1) ® a(n1)). q
I
q,l
One readily verifies that the above definitions actually do endow homR(M, N) and M ® RN with the structure of an £module. 3.9 DEFINITION For MEL-mod, the set I(M) = {mE M I a(m) = m, a E G} will be called the G-invariant subset of M. Other notation, MG. Remark In general, I(M) is not an L-submodule of M, merely an l(L) submodule of M. The proofs of the following propositions are, for the most part, routine, and will therefore be omitted.
Simple Noetherian rings
52 3.10 PROPOSITION
Let M, N E L-mod. Then
D R is naturally a left £-module, namely, for all a
=
.L aqa E L, q
rE R,
We shall always denote this £-module by LR. 3.ll CoROLLARY
For MEL-mod, I(M) = homL(R, M).
D 3.12 PROPOSITION isomorphism
For all M, N, PEL-mod, the natural
homR(M ® RN, P) : : : : homR(M, homR(N, P)) is L-linear.
D
3.13 CoROLLARY homL(M ® RN, P) : : : : homL(M, homR(N, P)).
D
3.14 PROPOSITION ForME L-mod, M reflexive in Mod-R, the natural isomorphism M ~ homR(homR(M, R), R) = M** is an isomorphism of £-modules.
D
Skew polynomial ringst Let p be an endomorphism of a field k. A map () : k --+ k is called a p-derivation of kif 8(a + b) = 8(a) + 8(b) and 8(ab) = p(a)8(b) + 8(a)b hold for all a, bE k. Using k, p and ()one can define the ring R = k[t; p, 8] of skew polynomials in t, consisting of all polynomials
t
This section (Cozzens [72]) is reproduced from Journal of Algebra, Volume 23, October 1972, by permiBBion of Academic Press, New York.
53
Noetherian simple domains
where a 1 E k for each i, with the usual addition, multiplication being defined by ta = p(a)t
+
a( a) T/ a E k.
It is not difficult to verify that R = k[t; p, a] is a pli-domain and is principal on the right if and only if p is surjective. Since k[t; p, a] is never simple if a = 0 and k[t; p, a] is usually simple if p = id, one naturally asks whether k[t; p, a] can be simple if p is not surjective and a is a nontrivial p-derivation. If k is commutative, the answer is no. For by a lemma due to Cohn ([6Ia], Lemma page 537), if k is commutative, then any p-derivation a of k is inner [i.e., for some x E k, a( a) = p(a)x xa for all a E k] unless p is an inner automorphism of k. If a is an inner p-derivation of k determined by x E k, then one easily checks that the principal left ideal of R = k[t; p, a], R(t + x), is two-sided and nontrivial. Thus, one is naturally forced to consider noncommutative k. Theorem 3.I5 provides complicated sufficient conditions which lead to simple pH-domains. Finding a triple (k, p, a) satisfying the hypothesis of 3.I5 is where the fun begins. A remarkable construction due to Cohn [6Ia] and an embedding theorem due to Jategaonkar [69] ultimately produce (k, p, a). 3.I5 THEOREM Let E be afield of characteristic 0, p: E--+ E a ring monomorphism and a a p-derivation of E satisfying (a) pa + ap = 0. (b) If x E E satisfies xpn(a) = pn-i(a)x for all a E E where n ~ j ~ I are both arbitrary, then x = 0. (c) There does not exist an x E E such that for some mE N and for all a E E an[pm(a)]
+
xpm(a) = pm+n(a)x
n = I, 2.
(d) There does not exist an x E E satisfying p(x) = x and a(x) = 0 such that for some n E N and for all a E E,
an(a)
+
xa
= pn(a)x.
Then R = E[t; p, a] is a simple pli-domain. Proof Let I be an ideal of R such that 0 c I c R. Then
Simple Noetherian rings
54 I = Rf for some f tradiction. m
.L
Let f =
1=0
R, where f =F 0. The proof will be by con-
E
a 1t 1, where we can assume that am = I.
Case I. m = 2n. Given a EE,
fa
=
{3f for some f3 E E,
(3)
since I is an ideal. Expanding Eq. (3) and equating coefficients we obtain p2n(a) = {3, 2 a2n-1P n-l(a) = f3a2n-l• a2n-18p2n-2(a)
+
a2n-2P2n-2(a) = f3a2n-2• 2n
,2 a181(a)
=
p2n(a)a0.
(4)
1=0
By successive applications of (b) and (c), we obtain a 2n-l = a 2 n- 2 = ... = a 1 = 0. Now
i.e., (t 2n
+ ao)t
t2n+l
+ {3')/
ft
=
(t
=
(t
+ {3')(t 2n +
+ aot
= t2n+l
for some {3'
E
E,
a 0 ). Hence
+ p(ao)t +
8(ao)
+ f3't2n + f3'ao.
Thus {3' = 0 and, consequently,
a0
=
By (4) 82 n(a) + aoa = Thus f = t 2 n. Since
t2na
=
p(a0) and 8(a0 ) = 0. p2n(a)ao for all a E E contradicting (d).
i i=O
(~)p2n-2i[82i(a)]t2n-2i, J
p 2n- 2(8 2(a)) = 0 for all a E E. Therefore, 82(a) = 0 for all a E E, contradicting (c). Case 2. m = 2n + I.
55
Noetherian simple domains Proceeding as above, we obtain p2n+l(a) =
8(p 2n(a))
+
{3,
a2nP 2n(a) = f3a2n•
(5)
2n+l
,2
a181(a) = {3a0 •
1=0
Clearly, Eq. (5) contradicts (c). Thus, no suchf can exist, implying that I = 0 or I = R.
D
Definition of E, p and 8 Let k be any commutative field of characteristic 0 and denote by A, the free associative algebra over k on the free generating set B = {x0 , x 1 , ••• }. Since A is the free associative algebra on B, there exists a unique endomorphism p of A such that p(x0) = -x0
and
p(x1) = xt+ 1
Vi
~
I.
Clearly pis injective. We define
[x1, x 0] = p(x1)x0 - x 0x 1 Vi ~ I. Let k = k(t1n, i E N U {0}, n E N) be the rational function field in the indeterminates t1n over k. Let a be the k-endomorphism of k defined by a(t1n) = tt,n+l for all i EN U {0} and n EN. Let D = k[ Y, a] be the twisted polynomial ring in Y with coefficients in k. Let K be the left quotient field of D. If we set
x= 1
x:
t11 Y
then A ---+K is an embedding (seeJategaonkar [69]). Identify x1 with 1 E K. We shall extend p to K as follows: Define p(ton) = - t0 n Vn EN, p(ttn) = tt+l,n Vi ~ l, and p(Y) = y Clearly, pa = ap and
x
p(tol Y) = - tol Y p(t1, 1 Y) = tt+ 1 , 1 Y Vi ~ I.
Since pa = ap, p extends to a ring monomorphism of K and
Simple Noetherian rings
56
moreover, does what it should with respect to the generators of
A. Let E be the subfield of K generated over k by x 1 for all i ~ I and [x1, x 0 ] for all i ~ I. Define a p-derivation 8 of K as follows: 8(a) = p(a)x0
-
X0a
Va E K.
Clearly, p8 + 8p = 0 and E admits both p and 8. Also note that x 0 and x 0 2 ¢;E. (See Cohn [6la].) The following lemmas show that (E, p, 8) satisfies the hypothesis of Theorem 3.15. Remark Tcq = {a ETc I a( a) = a} = k and
kP
= k(tol2, to22, • • •' ton2• • • • ).
3.16 LEMMA IfaEK andatn 1 Y = tn- 1 , 1 Yawheren- j ~ 0, for all n ~ N > 0, N some suitably large integer, then j = 0
and aE k. Proof Set tn 1 Y = tn Y and assume that a E K is of the form
Now,
and
where Therefore, tn _1 Y a =
(~ tna( a
1)
Y
1
by definition of multiplication inK. If
then, in particular,
)
I(~ c Y 1
1 )
57
Noetherian simple domains Hence,
Thus,
thus, am1a(bm)/a(am1)bm = am(tn-N~\tn)
Vn ~ N.
If m # m 1 or j > 0, let n --+ oo to get the desired contradiction. Hence, m = m 1 andj = 0. Now C0 = a(b 0 ), d 0 C0 = e0 b0 and d0 tna(a0 ) = e0 a 0 tn. Therefore, a(a0 )ja0 = e0 /d 0 =
C0 /b 0
= a(b 0 )/b0 ,
implying that a(a0 jb 0 ) = a 0 jb 0 • Thus, where
a 0 = ab 0
a E k.
(8)
and
Now c1 = ta(b 1 )/a(t)
and
a(b 0 ) =
C0 •
By substituting these expressions in (8) we obtain d0 ta(b 1 )/a(t)
+ d 1 a2 (b
0)
= eobl
+
ela(b 0 ).
Since a0 = ab 0 , we obtain d0 ta(ab 1 )
+ d 1 a(t)a2 (a
0)
= e0 a(t)b 1
+ e1a(t)a(a
(10)
ab 1 ).
(II)
0 ).
Comparing (9) and (10), we obtain t(a(a1 )
-
a(ab 1 )) = (a(b 0 )/b0 )a(t)(a1
-
Equation (II) holds for all n ~ N (remember, t = tn)· If a 1 - ab 1 # 0, letting n--+ oo produces a contradiction.
Simple Noetherian rings
58
Assume a 1 = ab1 for all i :::; m - I by induction. By a process similar to the above (by examining the coefficient of ym+k- 1 in (6) and (7)), we obtain am+k-1(t)ek-1ak-1(abm)
+
am+k-1(t)ekuk(abm-1)
- dkak(t)ak+ 1(abm_ 1) = am+k-1(t)ek-1ak-1(am)
+
am+k-1(t)ekuk(am-1)
- dkak(t)ak+ 1(am_ 1).
Thus, am = abm and hence, a= aE k.
3.17 LEMMA aEk.
D
If aE E satisfies p(a) =a and 8(a) = 0, then
Proof We can assume once again that a=
(i a P)/(I b Y 1
1
1=0
8(a)
1 ),
= 0 implies that t01 a(a) = at01 • Lett =
and at=
(~ a1a1 (t)Y1 )/(~ b
(~ c1 Y 1)t
=I.
bm
I =0
1
=
t 01 ,
Yl
t(~ a(b1)Y1) ,
where c1 = ta(b1)fa1(t) for all 0 :::; i :::; m. Thus,
If
then, in particular, dkak(cm) = ek and dkak(ta(an)) = ek(ak(anan(t)))
59
Noetherian simple domains since
d(~ ta(a1)Y1)
=
e(~ a1a1(t)Y1)
by definition of equality inK. Therefore, ta(an)fanan(t) = tjam(t)
implying that (12) Now,
since p(a) = a. Therefore if
(~f1 P) (~ p(b )P) 1
=
(~ g Y (~ b Y 1
1 )
1
1 ),
Aak(p(bm)) = gkbm
or A = gk since bm = I. Thus, p(an) = an by definition of equality in K. By (12) and the definition of p, m = n and a(an) = an. Thus, an= a E k. Now, dk-1ak-1(cm)
+ dkak(cm-1)
= ek-1ak-1(bm)
+ ekak(bm-d
and dk_ 1ak- 1(ta(am))
+ dkak(ta(am-d) = ek-1ak-1(amam(t))
+
ekak(am-1am-1(t)).
Therefore, ekak+m-1(t)[ak(abm-1 - am-1)] = dkak(t)[ak+1(abm-1 ~ am-1)], ek = dkak(cm)·
Hence Cmam- 1(t)[abm-1 - am-1J = ta(abm-1 - am-1)
or assuming that abm _ 1
-
am_ 1 # 0,
tam- 1(t)jam(t)t = a(abm-1 - am-1)/(abm-1 - am-1).
(13)
Simple Noetherian rings
60 fk-1ak- 1(p(bm))
+ Aak(p(bm-1)) =
Yk-1ak- 1(bm)
+ gkak(bm-1) (I4)
and fk-1ak- 1(p(am))
Yk-1ak- 1(am)
+ Aak(p(am-1)) =
+ gkak(am-1).
Therefore, fkak(p(abm-1 - am-1))
=
gkak(abm-1 - am-1)
and A = gk imply that p(abm-1 - am-1) = abm-1 - am-1 =
Thus,
fJ E JcP.
fJ.
By (I), a({J)a[am- 1(t)] = {Jam- 1(t). Therefore, {Jam- 1(t) = yEkq = k.
Thus am_ 1 = abm_ 1 since p(fJ) = fJ and p(y) = y. Assume by induction that a; = ab; for all I :::; j :::; m.
and k
k
1=0
1=0
,2 d 1a 1(ta(an_ 1)) = ,2 e a (an_ an- (t)). 1
1
1
1
Consequently, dk[ak+ 1(a0
-
=
ab 0 )]
by induction. As before, p(a0 = ab 0 • Therefore, a = a E k.
a0
ek[ak(a0
-
ab 0 ) = (a0
-
ab 0 )] -
ab 0 ) and hence
D
3.I8 LEMMA (E, p, 8) satisfies the hypothesis of Theorem 3.I5. Proof (a) p8 + 8p = 0 is trivially satisfied by construction. (b) If there exists an x E E such that Va E E, xpn(a) = pn-i(a)x
n 2: j 2: I
then in particular, xpn(x1) = XXn+l = xtn+ty = pn-i(x1)x = tn-i+t, 1 Yx,
Vi > 0, contradicting 3.I6.
Noetherian simple domains
61
(c) Note that 8(a) = p(a)x0 - x 0 a and 82 (a) = p2 (a)x0 2 Xo a, Va E E by definition of a and 82 • If
-
2
8(pm(a)] = pm+l(a)x - xpm(x)
where x
E
E
E
E,
E, then pm+ 1 (a)(x 0
Va
Va
x)
-
=
(x0
-
x)pm(a)
E contradicting (b).
A similar argument works for the n = 2 case. (d) If there exists an x E E satisfying p(x) = x and 8(x) such that for some n EN and for all a E E, an(a)
then by 3.17, x
E
+
xa = pn(a)x,
k. Thus, an(a) = x[pn(a) - a]
which just cannot happen.
D
Jacobson domains We complete this chapter with yet another class of simple domains which we call Jacobson domains. If Dis any field with center C, and if the polynomial ring D[x] is primitive, then D Q9 cC'(x) is a simple pli- and pri-domain, not a field. This holds, for example, whenever Dis transcendental over C, that is, whenever there exists dE D which is not algebraic over C. The first proposition is taken from Jacobson [43]. 3.19 PROPOSITION If Dis afield with center C, then every ideal I of the polynomial ring D[x] is generated by a central polynomial p(x) E C[x]. Proof Since R = D[x] has a right and left division algorithm
R is a principal (right and left) ideal domain. Thus I = p(x)R, for some monic p(x) E R of least degree. Then, Vd E D, r(x) = dp(x) - p(x)d is a polynomial in I of lower degree. It follows that r(x) = 0, and so p(x) commutes with every d E D, hence p(x) lies in the center C[x] of R. D 3.20 THEOREM (Jacobson [64a]) If Dis afield, then D[x] is not primitive if and only if every nonzero f(x) E D[x] is a factor
Simple Noetherian rings
62
of a nonzero central polynomial, that is, iff Vf(x) =F 0 there exist g(x) E D[x] and 0 =F p(x) EC[x] withf(x)g(x) = p(x). Proof R = D[ x] is primitive iff there exists a simple faithful right module V, or equivalently some maximal right ideal m(x)R contains no nonzero ideal. Using the last proposition we see that R is not primitive iff every maximal right ideal m(x)R contains a nonzero central polynomial p(x) that is, iff m(x) is a factor of a nonzero central polynomial. However, this is equivalent to stating that every nonzero f(x) is a factor of a nonzero central polynomial, since f(x) a product of irreducible polynomials m 1 (x), ... , m1(x), and every irreducible polynomial m(x) generates a maximal right ideal. D
In the next theorem, C(x) is the field of rational functions over C. 3.21 THEOREM Let D be a field with center C. Then A = D ® cC(x) is a simple pli- and pri-domain embedded in the right quotient field Q of D[ x ]. Moreover A = Q iff D[x] is not primitive. In particular, whenever D is transcendental over C, then A is not a field. Proof We know that Q exists since D[x] is a right Ore domain. (Any polynomial ring over an Ore domain is an Ore domain.) Furthermore A embeds in Q under the mapping
f(x) ® p(x)- 1 r-+f(x)p(x)- 1
defined for all f(x) D[x], then
E
D[x], p(x)
E
C[x]. If A = Q, and if f(x)
E
f(x)-1 = g(x)p(x)-1
for suitable g(x)
E
D[x] and p(x) EC[x], so f(x)g(x) = p(x)
is a factor of a central polynomial. Conversely, if the latter holds for any f(x) E D[x], then A contains f(x)- 1 = g(x)p(x)- 1 for any f(x) =F 0, so that A 2 Q, and hence, A = Q. We complete the proof by showing that D[x] is primitive whenever Dis transcendental. Lett ED, and suppose that t(x
+
l)h(x) = p(x)
Noetherian simple domains
63
is a factor of a central polynomial p(x) # 0. Write p(x) = a 0 h(x) = d 0
+ a 1x + ... + anxn, + d 1x + ... + dmxm,
where a 1 E 0, d; ED, Vi,j. Then, m = n - I, and comparing coefficients, we see that ao =do, d0 t d1 t dn-2t
+ d1 + d2
= a 1, = a 2,
+ dn-1
= an-1• dn-1t = an.
Then, solving recursively for dt> i = 0, ... , n - I, yields dn_ 1 as a polynomial of degree n - I in t with coefficients in C; d 1 = -a0 t - a 1 , d 2 = -a0 t 2 - a 1t - a 2 , ••• , and Thus, a 0 tn
+ a 1tn- 1 + ... + an_ 1t + an
= 0
so that t is a zero of a nonzero central polynomial, that is, t is algebraic. Using 3.20, we see that whenever D[x] is not primitive, then D must be algebraic. D
4. Orders in simple Artin rings
In this chapter we study rings which are right orders in simple Artin rings and explicitly determine these via the Goldie and Faith-Utumi Theorems. We also present some further results concerning representations of semiprime maximal orders. Although the rings considered are more general than simple Goldie rings, the conclusions and the techniques of proof are invaluable in the structure theory of simple Goldie rings. Recall that a right ideal I of R is called nil if for all x E I, xn = 0 for some n > 0. The identity (ra)n+ 1 = r(ar)na for elements a, r E R shows that Ra is a nil left ideal iff aR is a nil right ideal. Thus, R has no nil right ideals =F 0 if and only if R has no nil left ideals =F 0. LetS be a ring satisfying the maximum condition for right annulets. If S has a nonzero nil right or left ideal A, then S contains a nonzero nilpotent ideal. Proof (Utumi [63]) By the preceding remark, we can assume A is a nil left ideal =F 0. Let 0 =F a E A be such that a.L is maximal in {x.L I 0 =F x E A}. If u E Sis such that ua =F 0, then (ua)n = 0 and (ua)n- 1 =F 0 for some n > I. Since [(ua)n- 1 ].L 2 a.L, and since uaEA, it follows that [(ua)n- 1].L = a.L. Since ua E [(ua)n- 1 ] \ then aua = 0. Thus, aSa = 0, and then (a) 3 =0, where (a) is the ideal of S generated by a. D 4.1 LEMMA
4.2 LEMMA Let R be any ring which satisfies the (a.c.c.).L and (a.c.c.)Ei). If a E R there exists n > 0 such that anR + an.L is an essential right ideal. Proof There is an n 2: I such that an.L = an+ u. Then an R (") an.L = 0. Let I be a right ideal and suppose that
+ an.L) = nJ + ... is
I (") (anR
0.
Then the sum I + an] + a direct and, because R has (a.c.c.)Ei), we conclude that I = 0. D 2
[ 64 ]
Orders in simple Artin rings
65
As an immediate consequence of 4.2 we have that if x satisfies x.L = 0, then xR is an essential right ideal of R.
E
R
4.3 DEFINITION A ring R is said to satisfy the right Ore condition if given a, bE R, b regular, 3a1 , b1 E R, b1 regular, such that ab 1 = ba1 • It is easy but somewhat tedious to show that R has a right quotient ring if and only if R satisfies the right Ore condition. (See, for example, Jacobson [64a], or Faith [73a], Chapter 9.) Recall that Z(R) = {x E R I x.L is an essential right ideal of R} is a right ideal of R, called the right singular ideal of R. It is easy to show that Z(R) is in fact, a two-sided ideal of R. The next theorem provides necessary and sufficient conditions for R to have a classical right quotient ring which is a (simple) semisimple Artin ring. 4.4 THEOREM (Goldie [58, 60], Lesieur-Croisot [59]) A ring R has a semisimple right quotient ring if and only if R is semiprime and satisfies (a.c.c.)® and (a.c.c.).L. Proof (Goldie [69]) We first assume that R is a semiprime ring satisfying (a.c.c.)® and (a.c.c.).L, and prove that an essential right ideal E contains a regular element. E is not a nil ideal by 4.1, so it has an element a 1 # 0 with a/ = a 1 2 .L. Either a 1 .L (") E = 0 or a 1 .L (") E # 0. In the latter case, choose a 2 E a 1 .L (") Ewith a 2 # 0 and a 2 .L = a 2 2 .L. If a 1 .L (") a 2 .L (") E # 0, then the process continues. At the general stage we have a direct sum
a1 R
E8 ... E8 akR E8 (a/ n ... n ak.L n
E),
where ak E a 1 .L (") ••• (") ak _ 1 .L (") E, ak # 0 and ak .L = ak 2 .L. The process has to stop, because R has (a.c.c.)Ei). Let this happen at the kth stage. Then
a/ n ... n ak.L n E
= 0
=a/ n ... n ak.L
and hence (a12
+ ... +
ak 2).L
=a/ n ... n ak.L
= 0.
Let Z be the singular ideal of R and z E Z. Then zn R ® zn.L is
66
Simple Noetherian rings
an essential right ideal for some n > 0 and zn.L is also essential. Hence zn R = 0. Thus, Z is a nil ideal and hence is zero. Set c = a 12 + ... + ak 2 E E; as c.L = 0 we deduce that cR is essential by 4.2. Hence .Lc s;; Z, so that .Lc = 0 and c is a regular element. This establishes the existence of regular elements in R. Suppose that a, d E R with d regular and E = {x E R
I axE dR}.
Then dR is essential and hence so is E, so that E contains a regular element d 1 • Thus, the right Ore condition is satisfied and R has a right quotient ring Q. Next suppose that F is an essential right ideal in Q, then F (") R is essential in R. Now F (") R has a regular element, which is a unit in Q, and hence F = Q. Let J be a right ideal and K a right ideal of Q such that J (") K = 0 and J E8 K is essential (use Zorn's lemma); then J E8 K = Q. Thus, the module QQ is semisimple and Q is a semisimple ring. Conversely, let R have a semisimple right quotient ring Q. Then a right ideal E of R is essential if and only if EQ = Q. To see this, suppose I is a nonzero right ideal ofQ, then I(") R # 0 and I (") R (") E # 0, taking E to be essential in R. Hence I(") EQ # 0, which means that EQ is essential in Q; then EQ = Q as QQ is a direct sum of simple modules. On the other hand, when EQ = Q is given and I is a nonzero right ideal of R then IQ (") EQ # 0, trivially, and hence I (") E # 0, so that E is an essential right ideal of R. These conditions are equivalent to saying that E has a regular element, because whenever IE EQ, I = ee-l, e E E, c E Rand regular. On the other hand, when E has a regular element, then EQ = Q and E is essential in R. We now conclude that R is a semiprime ring, because if N is a nilpotent ideal of R, .LN is essential as a right ideal and hence, has a regular element. Thus N = 0. Let S be a direct sum of nonzero right ideals {Ia I a E A} of R which is essential as a right ideal. S has a regular element c, expressible as a finite sum
67
Orders in simple Artin rings
Now cR is essential and lies in Ia 1 + ... + I«n; it follows that A has only the indices a 1 , ••• , an, and R has (a.c.c.)Ei). Finally, the maximum condition holds for right annihilators, because R is a subring of the Noetherian ring Q. D 4.5 CoROLLARY A prime ring R has a simple Artinian right quotient ring if and only if R satisfies (a.c.c.)® and (a.c.c.).L.
D A set M = {e11 I I :::; i, j :::; n} of elements of R is called a set of n x n matrix units of R if
and n
,2 e11 =I 1=1
for all i,j, k and l. (8 1k is the Kronecker delta.) Faith-Utumi theorem
IfF is a right order in a ring D, then then x n matrix ring F n is a right order in Dn, and so is any ring R such that F n s;; R s;; Dn. The theorem below states that if D is a semisimple ring, every order R of Dn is obtained this way. 4.6 FAITH-UTUMI THEOREM[65] LetRbeanysubring-I of a matrix ring S = Dn, where D = centralizer 8 M of a set M = {e11} 1~1 = 1 of matrix units. Let
I aM
s;;
R}
B = BM = {bE R I Mb s;;
R}.
A = AM = {a E R
and Then n
BA = (BA n D)n =
_2
(BA n D)e11
t.J= 1
is a subring-I of R, AB is an ideal of R, and (BA) 2 s;; AB. Furthermore, F = BA (") D and U = B (") D = A (") D are
68
Simple Noetherian rings
ideals of P = R n D such that F 2 U 2 • Thus, R 2 BA = Fn 2 Un2• If Dn is a right quoring of R, then M can be so chosen so that A contains a unit a of S, B contains a unit b of S, and BA = Fn is a right order of Dn equivalent to R and to P n· If R is also a left order of Dn, then any choice of matrix units M has these properties. When D is a semisimplet ring and Dn is a right quoring of R, then D is the right quoring of F, and Dn = {af- 1 I a E F n• regular f E F}. Proof Since AP s;; A, P B s;; B, and P s;; D, then P F s;; F, and F P s;; F, so that F is an ideal of P. Since B is a right ideal of R, then U = B (") D is a right ideal of P = R (") D, and U = A (") D is a left ideal of P. Furthermore, U 2 F = BAnD 2 (B n D)(A n D) = U 2 • Now, every element t E Dn has a unique representation n
t =
.L
tlieli, where
1,1=1
n
tli =
2: e ktek 1
1
E
D.
k=1
Thus, if t = ba E BA, bE B, a E A, then tii E BA (") D = F since M B s;; B and AM s;; A. This proves that BA = F n· Moreover, (BA) 2 = BABA s;; AB, since A is a left, and B is a right ideal. Now assume that Dn is a right quoring of R. First, let M' be any set of n x n matrix units of Dn, with centralizer D'. Clearly, there is a common denominator a in R of the elements in M', that is, a regular element a E R such that M'a s;; R. Then,
M = a- 1 M'a is a set of matrix units of S, and D = a- 1 D'a = centralizer 8 M
is a ring isomorphic to D'. Furthermore, a is a unit of S contained in A = {x E R I xM s;; R}.
t
This holds more generally for a.ny semiloca.l quoring Dn (Faith [71]). The original theorem of Fa.ith-Utumi [65] was stated for a. field D. (Some of 4.6 is taken from Faith [65].)
Orders in simple Artin rings
69
Moreover B = {y
E
R
I My s;; R}
also contains a unit b of S. We now show that any set M of matrix units of S, for which A and B just defined each contains a unit of S, has the stated properties. Since every set M of matrix units satisfies this requirement if R is also a left order in S, then every set of matrix units has the stated properties in this case. Since AB is an ideal of R, and since AB contains a regular element t = abE R, then Dn is a right quoring of AB, and every y E Dn has the form y = xt(ct)- 1 , for elements x, regular c E R. Since bSb - 1 = S, where S = Dn, every element yES has the form y = by1 b- 1 , fCir some y 1 = xr- 1 ES, where x, regular rE R. Thus,
with bxa E BA and braE BA. This proves that Dn is a right quoring of BA. Now bRas;; BA, and BA s;; R, so that BA is a right order of Dn equivalent to R. Moreover, since F is an ideal of P, then Fn is an ideal of Pn containing a regular element t. Thus, tPn s;; Fn, so Fn is equivalent to Pn. Assume that Dn is a semisimple right quoring of F n· Since semiprime right Goldie rings are Morita invariant, F is semiprime right Goldie and, hence, F has a semisimple right quoring Q. (IfF is a subring-1 of D, then the subring F' generated by F is semiprime right Goldie, with semisimple right quoring Q, and then Q is the right quoring of F.) Since every regular element f E F is regular in F n (identifying f with diag f), f - 1 E Dn> and in fact, f- 1 ED. Q can be embedded in D by a mapping which induces lp. Then, F n is a right order in Qn, and
However, Qn is semisimple, and hence every right regular element of Qn is a unit, so Qn is a right quoring of F n· This proves Qn = Dn, so that Q = Dis the right quoring of F. D
Simple Noetherian rings
70 Principal ideal rings
If R is a right order in Dn, the theorem of Faith and Utumi states that there exists an order F in D and an inclusion F n s;; R s;; Dn. Even though Fn is an order in Dn, the ring structure of R does not depend entirely on F n· Under a stronger hypothesis, however, it does.
4.7 PRINCIPAL RIGHT IDEAL THEOREM (Goldie [62]) If R is a prime ring and a principal right ideal ring, then there exist a right Ore domain F, an integer n > 0, and an isomorphism R::::::: Fn. Proof (Faith-Utumi [65]) Using the notation of 4.6, we can write B = cR, for some c E R. Since B contains a regular element, cis a regular element. Since e11 B s;; B, that is, e11cR s;; cR, then c- 1e11c = f 11 E F (i,j = I, ... , n). Now M = {111 I i, j = I, ... , n} is a complete set of matrix units in S, with associated field H = c - 1 De. Since M s;; R, R = n
.L f 11 K,
where K = H (") R. Since R is an order in Hn, then
1.1=1
K is an order in H; that is, K is an Ore domain.
D
F need not be a principal ideal ring (cf. Swan [62]). Nevertheless, F is right Noetherian and hereditary, since these properties are Morita invariant.
Supplementary remarks (I) Let R be a right order in the ringS = Dn, n > I. Iff is any idempotent of S such thatfS is a minimal right ideal, thenf = ac- 1 , with a, c E R. Thus e = c- 1fc is idempotent and 0 # ce E Se (") R. Since Se (") R # 0, it follows from primeness of R that (eS (") R)(Se (") R) # 0, so that eSe (") R # 0. Then the proof of 4.6 shows that F = eSe (") R is a right Ore domain, and D : : : : eSe is its right quotient field; we thus obtain that S : : : : Dn, where D contains a right Ore domain K, which is contained in R. This illustrates the precise nature of 4.6 which states much more. (2) Next we show that, in general, not every set M of matrix units has the property without the hypothesis that R is also a left order in S.
Orders in simple Artin rings
71
Let K be a right Ore domain with right quotient field D that is not a left Ore domain. Let x, y be nonzero elements of K such that Kx (") Ky = 0, and let R = (Kx Kx
Ky)· Ky
!) with a, c Kx, and !) is an arbitrary
[R is the set of all 2 x 2 matrices (;
E
b, dE Ky.] Since K is right Ore, if A = (;
element of D 2 , there exists q E K, q # 0, such that aq, bq, cq, dq E K, and then
(ac db) (qx0 qy0)
B =
(qx0
Thus, A = BC- 1 , with B, C =
E
0 ) qy
R. E
R. Hence, R is a
right order in D 2 • As in the theorem, identify D with the subring of D 2 consisting of all scalar matrices ( ~
~)
with k E D. Now assume
for the moment that R contains a subring F 2 , where F is a domain £D. The contradiction is immediately evident since the form of R, R = (Kx Kx
Ky), Ky
where Kx (") Ky = 0, precludes the possibility of its containing a nonzero scalar matrix
(~ ~)
with dE K.
D
(3) A ring R, as in 4.6, need not contain nontrivial idempotents. Perhaps the simplest example is as follows: LetS = 0 2 be the ring of all 2 x 2 matrices over the rational number field Q,
and let R be the subring consisting of all matrices (;
!) ,
where b, c are even integers, and a, d are integers which are either both even or both odd. Then R = (2Z:) 2 + l is not an
72
Simple Noetherian rings
integral domain. However, R has classical quotient ring S but does not contain idempotents # 0, I. Maximal orders Throughout this section, all rings will be at least right orders in semisimple rings, i.e., semiprime right Goldie rings. The term order will be reserved for a semiprime two-sided Goldie ring. Recall that a right order R is maximal (left-equivalent, rightequivalent) provided that R s;; R' s;; Q and R ,.., R' (R ..!.. R', R ..!:.. R') imply that R = R'. 4.8 PROPOSITION (a) Let R, S be right orders with R s;; S, R ,.., S. There exist right orders T, T' such that
R s;; T s;; S, R s;; T' s;; S,
R ..!.. T
..!:..
S,
R ..!:.. T' ..!.. S.
(b) R is maximal iff R is a maximal left- and right-equivalent order. Proof Consult Faith [73a], p. 413-4. D
4.9 PROPOSITION A simple Goldie ring R is a maximal order inS. Proof SupposeS 2 R and Sa s;; R for some regular element a E R. Clearly, SaR = R by simplicity of R. Since 8 2 = S, SR = S(SaR) = S 2 aR = SaR = R. However, SR = S. Thus, S = R and hence R is a maximal left-equivalent order. Similarly, R is a maximal right-equivalent order and hence, by 4.8, a maximal equivalent order in Q. D
The essential argument used here was first used by Faith [65] who showed, interalia, that center R coincides with center Q. 4.10 PROPOSITION Let R be a maximal right order, MR a finite dimensional torsionless generator and k = End M R· If k' 2 k and k' :.., k, then R = End k'k' ® kM. Proof Set M' = k' ® kM and R' = End k'M'. Since k'M' is finitely generated and projective, M~. is a generator and hence, balanced, i.e., if k" = End M~., R' = End k.M'. Moreover, if kM = kne, k'M' = k'ne and R' = ek~e imply-
Orders in simple Artin rings
73
ing that R' is an order in the quotient ring of R. Thus, End M~, = End M~. Since ak' s; k, where a is a regular element of k, a induces a monomorphism M~-+ MR implying that M~ is finite dimensional, torsionless and hence, T = trace M~ =F 0. Since M~ is clearly faithful, T R' s; R by 1.6. However, T R is essential since M~ is faithful and torsionless. Thus, T contains a regular element of R implying that R' ..!:.. R and hence R' = R by maximality of R. D 4.ll PROPOSITIONt Let R be a maximal order, MR a finite dimensional torsionless generator, k = End MR, M* = homR(M, R) and M# = homk(M, k). Then (a) End M#k = End M*k = R (b) k' = End RM# = End RM* is an essential extension of k and hence, an equivalent order in the quotient ring of k. (c) dim RM* = dim M R (d) M* : : : : M***. Proof (a) Set R' = Biend RM# =End M#k and T = trace RM#. By 1.6, R'T s; R and since RM# is a generator, T = R. Thus, R' = R. (b) Since k' = Biend M#k, Tk' s; k where T = trace M#k. Hence, k' is an essential extension of k and, since Tis an essential right ideal of k, T contains a regular element of k and thus, k',.!:., k. (c) By 1.18(1), dim MR = dim kk and dim RM* = dim k'k'. Since both k and k' are orders and kk' is an essential extension of kk, dim kk = dim kk' = dim k'k' as claimed. (d) By (c), dim RM* = dim M**R = dim RM***. Since RM* is isomorphic to a direct summand of RM*** (see Jans [64], p. 67), we have RM* : : : : RM***. D
The next lemma allows us to assume in many instances that the module in question is a generator (Jategaonkar [71]). 4.12 LEMMA Let R be a maximal right order, M a finite dimensional, torsionless, faithful R-module and k = End M R· Then k is a maximal (right-equivalent, left-equivalent) order when-
t More generally, 4.11 holds for finite dimensional, torsionleBB, faithful M 8 • The proof is almost identical.
Simple Noetherian rings
74
ever End(M E8 Rh is a maximal (right-equivalent, left-equivalent) order. Proof Viewing the elements of M E8 R as column vectors, k- = End(M
E8 R)R =
( k M*
M) R
and its quotient ring JJ is Jj
= End((M E8 R) ® RQ)Q = ( End(M ®
RQ)Q homQ(M ® RQ, Q)
where Q = the quotient ring of R. Furthermore, D = End(M ® RQ)Q = the quotient ring of k (see Zelmanowitz [67]). Suppose Tc is maximal and k' 2 k with k' ""' k, say, ak'f3 s; k with a and f3 regular elements of k. Set k'
S
k'M )
-
= ( M*k' M*k'M + k.
Sis clearly an order in Jj containing Tc. Since
Tc(~ ~)TesTe(~ ~)Tc s; Tc (routine computation), S ""' Tc if the ideals
Tc(~ ~)Tc
Tc(~ ~)Tc
and
contain regular elements of Tc. To demonstrate
this, we shall consider only the first ideal. Since
Tc( ~ ~) Tc
contains all matrices of the form kak ( 0
0 ) [M*, aM]
such a regular element exists provided the ideal I = [M*, aM] is essential as a right ideal of R; equivalently, Ir = 0 ~ r = 0. If Ir = 0, aMr = 0 since M is torsionless. Thus, Mr = 0 (a is regular) ~ r = 0 since M is faithful. Consequently, I is essential as asserted. The proofs of the parenthetical statements are special cases of the above. D
Orders in simple Artin rings
75
When R is prime, Hart-Robson [70] have shown that eRne is maximal for all idempotents e E Rn and n 2: I. The argument used in the proof of 4.12 is essentially theirs. 4.13 THEOREM Let R be a maximal order and M a finite dimensional, torsionless, faithful R-module. Then End RM* = m is a maximal order and is the maximal right equivalent order containing k. Proof It suffices to show that whenever k' 2 k = End M R and k' ..!:.. k, k' s;; m and if k' 2 m with k' ..!.. m, k' s;; m. For if this condition is satisfied and k' 2 m with k' ""' m, k' ""' k and by 4.8 there exists an orders with k' 2 s 2 k, k' ..!.. s and s ..!:.. k. By assumption, s s;; m and since k' ..!.. s, k' ..!.. m. Thus, k' s;; m, and m is maximal as claimed. To show that the above condition is fulfilled, we can clearly assume that M is a generator by 4.12. If k' 2 k with k' ..!:.. k, set M' = k' ® kM. By 4.10, R =End k'M' and clearly, homk.(M', k')--+ homR(M', R) is a monomorphism. Since MR is a generator, R =End kM and M#::::::: M*. Since M~ is an essential extension of IJJR, homR(M', R) 4 homR(M, R). One readily checks that the composition of maps
is the map defined by
f--+ JIM (restriction to M) Vf E homk,(M', k'). Thus, any k-linear map f: M --+ k' is actually a map into k since f induces a k' -linear J: M' --+ k' such that /I M = f. Next, if T = trace kM, Tk' s;; k. For, if (u)f E T, a' E k', fa' E homk(M, k') = homk(M, k) by the above remarks. Hence, (u)fa' E k. Finally, M#Tk' = M#k' s;; M# which implies that k' s;; m. In order to complete the proof, suppose that k' 2 m with k' ..!.. m. Then by an obvious modification of 4.10, R = End(M# ® mk')k'· By modifying the above argument, we obtain homm(M#, k') = homm(M#, m) and hence, k'T# s;; m where
76
Simple Noetherian rings
T# = trace M#m· Since m = End M**R (see the proof of (a) (c) in 4.14) and T#M** = M**, k' s;; mas claimed. D
~
4.14 MAXIMAL ORDER THEOREM Let R be a maximal order and M a finite dimensional, torsionless, faithful R-module. Then (a) ~ (b)~ (c), where (a) M R is R-reflexive, (b) k = End M R is a maximal order, (c) k = End RM*, where
M* = homR(M, R). Moreover, if M is a generator, then (b) ~ (a). Proof We shall first assume that M is a generator and prove the stated equivalences for this case. Then we shall discuss how the general case can be reduced to the case of a generator.
(a)
~(c):
Since M = M**, k = End MR = homR(M, M**) = homR(M*, homR(M, R)) = EndRM*.
The third equality follows from one of the standard functorial isomorphisms (e.g., see Cartan-Eilenberg [56], ex. 4, p. 32). (c)~ (b): Immediate by 4.ll and 4.13. (b) ~ (a): By 4.ll, k' = End RM# = k. Since M#::::::: M* and homk.(M#, k')::::::: homR(M*, R) = M**, M## : : : : M** as (k, R)-bimodules. By finite projectivity of kM, M## : : : : M as (k, R)-bimodules. Hence, M is R-reflexive as asserted. If M is no longer assumed to be a generator, note that M is reflexive iff M = M E8 R is reflexive, and End M R is maximal only if End M R is maximal. Moreover, M is always a generator for arbitrary M. Thus, (a) ~ (b), and (b) ~ (c) follows immediately from 4.ll(b). If k = End RM*, k is maximal by 4.13. Consequently, (c) ~ (b). D Remark To see that (b)
~
(a) does not hold in general, let
R be any maximal order having a faithful ideal I which is not reflexive as a right ideal and set k = End I R; e.g., any ndimensional regular local ring with n ;;:: 2. These are maximal
Orders in simple Artin rings
77
orders by Auslander-Goldman [60] and must have nonreflexive right ideals by Mattis [68]. Since k 2 R and k,.., R, k = R. Thus, I R is not reflexive but k is maximal. In order to generalize the above to maximal right orders, care must be exercised to insure that all of the endomorphism rings in question are right orders in the appropriate semisimple ring. For example, if MR is a finite dimensional torsionless generator, there is no guarantee that k' = End RM* is a right order in the quotient ring of k. However, when R is prime and M R reflexive, we can conclude that k is maximal. Specifically, 4.15 PROPOSITION Let R be a prime maximal right order, M R a finite dimensional reflexive R-module and k = End M R· Then k is a maximal right order. Proof Since 4.12 is valid for right orders, it suffices to assume that M R is a generator. Moreover, the proof of 4.13 shows that if k' . !:.. k or k' ..!.. k, Tk' s;; k provided that R = End k'k' ®k M. This, of course, implies that k is maximal. Thus, it suffices to show thatifk'..!.. k, R = Endk,k' ®kM(4.10coversthecasek'..!:.. k). To that end note that for some n > 0, R' = End k'k' ®k M : : : : ek~e and R : : : : ekne. Since k' a s;; k, ek~eknekna.ekne £ ekne where a = ai n• In the n X n identity matrix. Since ekne is prime, the ideal eknekna.ekne is essential and hence, contains a regular element of ekne. Thus, ek~e . !:.. ekne ~ ek~e = ekne by maximality of R(ekne). D The question of whether one-sided versions of 4.13 and 4.14 hold for general semiprime R remains open. If k' ..!.. k always implies ek~e ..!.. ekne, then, of course, the above argument shows that finite dimensional, faithful, reflexive modules have maximal endomorphism rings. As an interesting aside, note that the proof of 4.15 shows that m = kT, the (left) quotient ring of k with respect to the smallest filter of all left ideals which contain T = trace kM. The case of global dimension at most 2
In order to show that reflexive generators, specifically in the case of maximal orders, are bonafide generalizations of finitely
78
Simple Noetherian rings
generated projective generators, we shall show (4.17) that if each finitely generated reflexive module is projective, then the global dimension of the ring cannot exceed 2 (the converse is well-known). Then, if U R is any finitely generated reflexive nonprojective (necessarily r.gl.dim R > 2), U R E8 RR is a nonprojective reflexive, generator. For simplicity, we shall assume that R is a semiprime two-sided Noetherian ring. To prove the above assertion we need the following characterization of twosided Noetherian rings of global dimension ~ 2. 4.16 PROPOSITION (Bass [60]) If R is left and right Noetherian, the following are equivalent: (a) r.gl.dim R ~ 2. (b) The dual of any finitely generated right R-module is projective 0 Let MR be any finitely generated R-module and t(M) its torsion submodule. We can assume that MR is a generator by theremarks preceding the conclusion of the proof of 4.14. Clearly, M* = (Mjt(M))* since (t(M))* = 0. Thus, we can further assume that M is a torsion free and hence, a torsionless, finitely generated R-module. Since M R is clearly finite dimensional, RM* : : : : RM*** and assuming reflexive modules are projective, M* is projective. Consequently, by 4.16, r.gl.dim R ~ 2. Thus, we have shown that 4.17 PROPOSITION The following conditions are equivalent for any semiprime two-sided Noetherian ring R. (a) r.gl.dim R ~ 2. (b) each finitely generated reflexive module is projective. 0 A canonical and important example of a reflexive module is given by 4.18 PROPOSITION Any maximal uniform right ideal of R (more generally, any right annulet) is reflexive. Proof By Bass [60] U = X* for some finitely generated left R-module X. Since we can assume that X*R is a generator, dim X*R =dim X***R and consequently, U =X* =X*** =
U**.
0
Orders in simple Artin rings
79
By parroting an argument used in Proposition 2.26 we readily obtain the necessity of the following characterization of simple Noetherian domains having global dimension less than or equal to 2. 4.I9 THEOREM (a) Let R be a simple two-sided Noetherian domain. Then r.gl.dim R :::; 2 iffVn ~ I, whenever B is a maximal order and B ~ Rn, B is simple. (b) If R is simple Noetherian with r.gl.dim R :::; 2, MRfinite dimensional and torsionless, then k' = End RM* is a simple Noetherian ring Morita equivalent to R. Proof (b) Since M R is finite dimensional and torsionless, M R 4 R
As a final remark regarding uniform right ideals we have If R is a simple two-sided Noetherian ring satisfying r.gl.dim R :::; 2 and each uniform right ideal is reflexive, then R is hereditary. Proof We can assume R is a domain by 4.I9. Since each right ideal is now reflexive, each right ideal is projective by 4.I7. 4.20
REFLEXIVE
IDEAL
THEOREM
80
Simple Noetherian rings
Thus, even in such well-behaved rings, one cannot expect to find too many reflexive uniform right ideals.
The nonreflexive case The object of this section is to provide further insight into the structure of the endomorphism ring of a finite dimensional torsionless R-module M, in particular, a basic right ideal of R, and to sharpen Faith's representation theorem mentioned in the introduction. In 4.21 we shall assume that R is simple. While 4.21(b) is 4.13 in a less general setting, its proof is an interesting application of the correspondence theorem. 4.21 PROPOSITION Let R be a simple order, MR a finite dimensional torsionless R-module and k = End M R· Then (a) k is a maximal left equivalent order: (b) m = End RM* is the maximal equivalent order containing k. Proof (a) MR is necessarily a generator for mod-R. LetT = trace kM. If k' 2k with k' ..!.. k, say k'a s;; k, then k'aT = T = k' T since T is the least ideal of k. Thus, k' T M = k' M s;; M and hence k' s;; k. (b) If k' 2 k with ak' s;; k, Tak' = T = Tk' ~ k' s;; m since M*T = M*. Thus, any equivalent order containing k is contained in m implying that m is the maximal such order. D 4.22
PROPOSITION
(a) (Faith [64]) Any maximal order in
Q = D n• D a field, is isomorphic to the biendomorphism ring of any right ideal U, say R : : : : End k U where k = End U R· (b) If URis a maximal uniform right ideal, then k = End U R is a maximal order in D. Proof (a) Let U be any right ideal of R. By 1.6, T = trace U R satisfies T R c R where R = Biend U R· Since T contains a regular element of R, R is a right order of Q which is ..!:.. to R. Thus, R = R by maximality of R. (b) Clear. D Examples In this section we show that if A = End 8 V is simple with 8 V finitely generated projective and B right Ore, B can be quite 'bad' when A is quite 'good'.
Orders in simple Artin rings
81
In the following examples, we shall freely use results from Robson [72] and certain generalizations which can be found in Goodearl [73]. These references will be abbreviated to [72] and [73] respectively. ExAMPLE I For any n 2: 2, there exists a right but not left Noetherian domain B with l.gl.dim B = r.gl.dim B = n, a finitely generated projective left B-module 8 V such that A = End 8 V is a simple pri(pli)-domain. Let k ::::> k' be fields with l.dim k'k = oo and r.dim kk' finite (see Cohn [6Ia] for such examples). Set A = !!)k<x> where S is defined in the obvious fashion: S(x) = I, S(a) = 0
Va
E
k.
By Example 7.3 in [72], the subring B = k + SA of A is a hereditary Noetherian domain. By Theorem 4.3 of [73], B' = k' + SA is a two-sided order in A with l.gl.dim B' = r.gl.dim B' = 2. Moreover, B' is right Noetherian and not left Noetherian. Finally, set V = SA. First, Vis finitely generated and projective in B'-mod. For V* 8 , 2 A and A V = A. Thus, IE V*V implying finite projectivity of 8 , V by the dual basis lemma. Moreover, End 8 , V is an equivalent order containing A and hence, A = End B' V. By an obvious modification of this technique, we can choose B' such that B' is a two-sided order in A, B' is right but not left Noetherian and l.gl.dim B' = r.gl.dim B' = n. Moreover, B' can be chosen to be neither right nor left Noetherian but still a two-sided order, having any prescribed global dimension 2: 2. ExAMPLE 2 (Real Pathology) Let R be a pri-domain, D its right quotient field and suppose that DJR is semi simple in mod-R. Then there exists a right hereditary, right Noetherian domain B, which is, however, a two-sided order, a finitely generated projective 8 V such that A = End 8 V is a simple pri(pli)-domain.
82
Simple Noetherian rings
Set S = !!)D<x> where a is the standard formal derivative of D(x), T = D + as and k = R + as. As before, T is a hereditary Noetherian domain. Also k £ S since as c k. Thus, k is a two-sided order in F = right quotient field of S. We claim that k is right hereditary. First, one readily verifies that the exact sequence of k-modules 0-+ TjaS -+SjaS ~ SJT-+ 0
is split exact (the obvious map is the desired right inverse to 1r) and hence, pd(SjT)k ~ pd(SjaS)k· Since Sk is projective by Lemma 2.I in [72], pd(SjaS)k ~ I and hence, pd(SjT)k ~ I, implying that Tk is projective. Since k is an order in T, it is easy to see that T ® kT = T. As an immediate consequence, we have pd Mk = pd MT for all ME mod-T by a proof similar to that of Lemma 2.8 in [72]. Moreover, since DJR is semisimple in mod-Rand isomorphic to Tfk, Tfk is semisimple in mod-R and hence, in mod-k. Finally, let I be any right ideal of k. Then IT is projective in mod-k and ITJI is a direct summand of a coproduct of copies of Tfk. Since Tk is projective, pd Tfk ~ I implying that pd ITJI ~ I. Hence, pd I k = 0. Thus, k is right hereditary and since it is an order in a field, k is right Noetherian. Note that if we set V = as, S = End k V. We also remark that such rings as R exist. For example the rings discussed in Chapter 5 work. The existence of an example principal on the right but not on the left remains an open problem. However, we feel very strongly that such examples do exist. Note that R in Example 2 does not have to be left Ore! Finally, if such an R exists (which is not left Noetherian), then k affords us with an example of a two-sided order which is right hereditary but not left hereditary, thus answering a question raised in Camillo-Cozzens [73].
5. V-rings
In 1956, Kaplansky showed that a commutative ring A is Von Neumann regular iff each simple A-module is injective. Thus, a very natural and important class of commutative rings could be completely characterized by their siiP_ple modules and a fundamental homological property, namely, injectivity. However, this property does not characterize noncommutative regular rings, since, as Faith showed, some regular rings have injective simple modules, while others do not, whereas Cozzens [70] constructed simple pH-domains, not fields having simple modules injective. We present these examples in this chapter. We also show that any right Goldie V-ring is a finite product of simple V -rings. Dual to the notion of projectivity and of interest to us in this and succeeding chapters will be the concept ofinjectivity. For a proof of 5.1 and the statements regarding the injective hull, consult Faith [73a] or Lambek [66]. 5.1 PROPOSITION AND DEFINITION A module MR is called injective if it satisfies any of the following equivalent conditions: (I) The functor hom R(- , M) : mod- R "-" Ab is exact. (2) Every exact sequence 0 -+ M
-+
M'
-+
M"
-+
0
splits. (3) (Baer's criterion) Iff: I -+ M is a map of a right ideal I of R into M, there exists an mE M such that f(x) = mx for all
x
E
I.
D
Given any module M, there exists an injective module 1fiR• unique up to isomorphism, satisfying the following equivalent properties: (l) MR is the maximal essential extension of M. [ 83 ]
Simple Noetherian rings
84
(2) 1ftR is the minimal injective extension of M. 1ftR is called the injective-hull of M and is denoted variously by 1ft or inj hull M R· There is an interesting connection between the ascending chain condition and injectivity, namely, 5.2 PROPOSITION The following are equivalent for any ring R: (I) R is right Noetherian. (2) If {St : i E I} is any family of simple modules, L E8 sl is tel
injective. (3) Each direct sum of injective modules is injective. Proof (After Bass) We shall show that (2) ~ (l) leaving the other implications for the reader. Let I 1 £ I 2 £ . . . be an ascending chain of finitely generated right ideals. Since the I 1 are finitely generated, we can embed the above chain in
I1 £ M2 c I2 £ M3 c I3. · ·, whereitfMtissimple'v'j
~
2.SetE1
= ------I 1fM1 andE = .L j;,
2
®E1 •
By hypothesis, E is injective. If I = ui1, there is a map -+ E defined as follows:
f :I
f(i) =
2: i + M
1
Vi
E
I.
j;,2
i
The sum on the right is of course finite since eventually, I 1, 'v'j ~ n. By 5.1, f extends to all of R ~ imf £ finite
E
summand of E, say
n
.L E8 E 1• This readily implies that In+ 1
=
i= 2
In+ 1, 'v'j
~
2 and hence the chain terminates.
D
There is another useful characterization of Noetherian rings, due to Matlis [58] and Papp [59] (generalized by Faith and Walker [67]) which states that R is right Noetherian if and only if each injective module is a direct sum of indecomposable injectives. We remark that the necessity is an immediate consequence of 5.2, and the obvious fact that over a Noetherian
85
V-rings
ring, every nonzero module has a uniform submodule. The sufficiency is however, more difficult. By modifying 5.1(1) we obtain the more general but very useful concept of quasi-injectivity. 5.3
DEFINITION
ME mod-R is called quasi-injective if
exact implies 0-+ homR(MfN, M)-+ homR(M, M)-+ homR(N, M)-+ 0 exact, i.e., every map f: N-+ M where N s;; M is induced by an endomorphism of M. Note that every semisimple module is quasi-injective, thus, attesting to their importance. There is a very easy way to identify these modules: they are the fully invariant submodules of their injective hull. 5.4 PROPOSITION (Johnson-Wong [61]) MR is quasiinjective if and only if AM = M where A = End 1ftR· Proof That AM is quasi-injective is obvious. Conversely, suppose that MR is quasi-injective and that ,\EA. We must show that .\M s;; M. Set N = {mE M I ,\mE M}. If N =F M, by quasi-injectivity, there exists a .\1 E End M R such that .\ 1m = .\m, Vm E N. By injectivity of 1ft R• there exists a ,\~ E A such that ,\~m = .\ 1m, Vm EN. Since .\ 1 M s;; M, .\M s;; M if (.\~ - .\)M = 0. Now (.\~ - .\)M =F 0 ~ (.\~ - .\)M n M =F 0 since 1ft\} M. However, if 0 =F m' = (.\~ ·- .\)mE (.\~ - .\)M n M, .\m = .\ 1m - m' EM ~ mEN ~ .\ 1m = .\m a contradiction. Thus, N = M and the proof is complete. D Although it will be used only briefly, we shall introduce the concept of a cogenerator which is dual to the notion of a generator. 5.5 PROPOSITION AND DEFINITION A module CR is called a cogenerator if it satisfies any of the following equivalent properties: (I) The functor homR(-, C) : mod-R "-" Ab
86
Simple Noetherian rings
is faithful, i.e., given a nonzero f: M--+ N there exists g: N--+ C such that g of =F 0. (2) For each ME mod-R there exist a set I and an embedding M--+ C1 (product of I copies of C). (3) For each ME mod-R the canonical map M--+ ChomB<M.CJ is a monomorphism. (4) Given any simple moduleS, there is a monomorphism S--+
c.
Proof The proofs of (l) ~ (2) ~ (3) are dual to those given for the dual statements in I. I and (l) ~ (4) is obvious. (4) ~ (l) Let f: M--+ N be any nonzero map and f(x) = yEN be nonzero. yR ::::; Rfyl. and yl. s;; J, a maximal right ideal.
By assumption, there exists a monic h : RfJ--+ ------ C. Thus, we obtain a map g' : yR--+ RfJ ------ defined by the composition yR--+ Rfyl.--+ RfJ--+ RfJ. ------
By injectivity of RfJ, -------- g' extends to a map g": N--+ RfJ. ------ It is easy to check that the composition g = h o g" : N --+ C is the required map satisfying go f =F 0. D 5.6 DEFINITION A ring A is called a right V-ring if each simple right A-module is injective. 5.7 THEOREM Let R be a right V-ring. Then the following conditions are equivalent: (I) Each simple right R-module is injective. (2) Each right ideal is the intersection of maximal right ideals. (3) The radical of M, Rad M = 0 for all ME mod-R. Proof (l) ~ (3): Let 8 1, i E I be a set of representatives of the distinct isomorphism classes of simple R-modules. Then, 8 1 is an injective cogenerator in mod-R. Hence, clearly, C =
n
tel
for ME mod-R, there exists a monomorphism 0--+ M --+ C1 (product ofC, I times). This readily implies that rad M = 0. (3) ~ (2): Obvious. (2) ~ (1): Let f be a map of a right ideal I into RJM where M is an arbitrary maximal right ideal. To show that RJM is
87
V-rings
injective, it suffices to show that f can be extended to R. Kerf = I 1 is such that xR + I 1 = I for some x E I. By (2), there exists a maximal right ideal M 1 of R such that I 1 s;: M 1 and M 1 +I= R. Now M 1 n I = M 1 n (xR
+
I 1) = I 1
+ (xR n
M 1) = I 1 •
Therefore, by defining J to be zero on M 1 and J = f on I, we obtain the desired extension off to R. 0 Remark (I) ~ (2) is credited to Villamayor (unpublished). As an obvious corollary to the above argument, we have 5.8 CoROLLARY If R is a right V-ring, and I is any right ideal of R, then J2 = I. 0 Note that this property is also enjoyed by any simple ring R. For I = I R = I RI R = J2. Finally, we obtain 5.9 THEOREM Let R be commutative. Then R is Von Neumann regular iff R is a V-ring. Proof If R is regular, so is RJI for any ideal I. Since rad(R/I) = 0, condition (2) of 5.7 is trivially satisfied. Conversely, if R is a V-ring and a E R, then aRaR = aR by 5.8. Thus a 2x = a for some x E R and hence R is regular. 0
In order to present Faith's example of a regular ring which is not a left V-ring (it is however a right V-ring!), we first summarize several useful categorial results. 5.I0 PROPOSITION If T:
right A -module. (2) The inclusion functor mod-AJB "-"mod-A preserves injectives.
88
Simple Noetherian rings
(3) The inclusion functor mod-AJB "-"mod-A preserves injective hulls of simple right AJB-modules. (4) AJB is flat as a left A-module. D 5.12 Co RO LLAR Y If A is a right V-ring, then, for any ideal B, AJB is a flat left A-module. D 5.13 CoROLLARY If A is a regular ring, then every injective right AJB-module is canonically an injective right A-module, for any ideal B of A. D 5.14 ExAMPLE Let L = End V F be the full right linear ring of an infinite dimensional right vector space V over a field F, let S be the ideal consisting of linear transformations of finite rank, and let R = S + F be the subring generated by S and the subring F consisting of scalar transformations (sending every v r-+ va for some a E F). Clearly, R(L) is a regular ring. By standard functorial arguments (LV is flat, V F is injective and L = End Vp), LL is injective, and since VL is a summand, VL is likewise injective. Moreover, LV is injective iff dim V F < oo (see Faith [72b], p. 163). First we show that R is a right V-ring. Let W be a simple right (or left) ideal of R, and let f: I--+ W be a mapping of a right (or left) ideal of R. In order to determine if W is injective, it suffices to assume that I is an essential one-sided ideal, and thus, that I contains the socle S of R (the sum of the simple right ideals of R). Since RJS is simple, either I = S, or I = R. If I = S, and f is a morphism of mod-R, then f is a morphism of mod-L, since
[f(xa) - f(x)a]s = 0 Vs
E
S, x
E
I, a E L.
Since W is a summand of Lin mod-L, then W is injective along with L, and so f has an extension to a mapping L --+ W which induces a mapping R--+ W extending f. This proves that W is injective in mod-R. If W is a simple right R-module not contained inS, then W::::::: RJS is injective over RJS, whence by 5.13 W is injective over R. This proves that R is a right V-ring. In order to prove that R is not a left V-ring, assume for the moment that V is injective in R-mod, and that f: I--+ V is a
89
V-rings
morphism in L-mod, where I is a left ideal of L. In order to extendf, we may assume that I is an essential left ideal, that is, that I 2 S. Then, f has an extension f' in R-mod, and f' is a morphism in L-mod, since
s[(ax)f' - a(x)f'] = 0 Vs
E
S, x
E
I, a E L.
But this implies that V is injective in L-mod, a contradiction. Thus, R is not a left V-ring. (This fact is also a consequence of Faith [67a], p. 103, Th. 3.1, which implies that the maximal left quotient ring of R is also a right quotient ring. This involves a contradiction.) Next we prove a lemma preparatory to the structure theorem for a right Goldie V-ring. 5.15 LEMMA If A is a right V-ring and I is an ideal of A, then I does not contain a right regular element of A. Proof Let M be a maximal right ideal containing I. Then AJM is injective and hence,
AfMx = AJM V right regular x. For, if x.L = 0 is arbitrary, there is a map xA --+ V defined by xa ~ va, Va EA. By injectivity, 3v' E V such that v = v'x ~ V s;; Vx. Finally, since AfMx = 0, Vx E I, I cannot contain a right regular element of A. D 5.16 THEOREM Let A be a right Goldie V-ring. Then A is a finite product of simple Goldie V-rings. Proof Since A is a right V-ring, rad A = 0, i.e., A is semiprime. Let I be a maximal ideal of A. If I = 0, A is already simple. Otherwise, I (") K = 0 for some K # 0 by the lemma (as seen in the proof of 4.4, essential right ideals contain regular elements), and since A is semiprime, J.L # 0. Consequently, A = I E8 J.L and AJI is clearly a simple Goldie V-ring. The proof is now completed by induction on I, a Goldie V-ring having dimension less than dim A. D
It is instructive to give an alternate proof of this theorem using another useful result.
Simple Noetherian rings
90
5.I7 PROPOSITION Let A be a prime Goldie V-ring. Then A is simple. D A ring R is the subdirect product of rings RfMt, i E I, if
nMt tel
=
o.
Alternate Proof If R is semiprime Goldie, the canonical ring homomorphism R--+
nn RfMt is an embedding, where RfMt is
t=l
a prime Goldie ring (see Jacobson [64a], p. 269). If R is a V-ring, so is each RfMt and hence, each RfMt is simple by the previous result. However, any subdirect product of finitely many simple rings is a direct product of simple rings. D 5.I8 PROPOSITION If A is a V-domain, then A is simple. Proof Let I be a nonzero ideal of A and 0 # a E I. aAaA = aA by 5.8. Thus, IE AaA which implies that I = A. D (For the background of 5.I6-I8, see Ornstein [67] and Faith [67a, 72a, b].) Let A be a hereditary 2-sided Noetherian right V-ring. By 2.33 each finitely generated torsion A-module (either side) is semisimple, and, since A is a right V-ring, each finitely generated torsion right A-module is injective. If in addition, A is a domain, we have, 5.I9 PROPOSITION Let A be a hereditary, two-sided Noetherian right V-domain. Then (I) each cyclic right A-module not isomorphic to A is injective; (2) each indecomposable injective right A -module is either simple or isomorphic to A; (3) each quasi-injective right A-module is injective. Proof (I) Clear. (2) Let E be an indecomposable injective. Then E = () for any cyclic submodule C. If C::::::: A, then E::::::: .A. Otherwise, C is injective and E = C which implies, of course, that E is simple. (3) Let Q be quasi-injective. Then Q = .L E8 Et, where each tel
Et is indecomposable and injective, and Et (") Q # 0, ViE I.
V-rings
91
Thus, we can assume that Q is indecomposable because Q = .L E8 (E; (") Q) and the obvious fact that each summand of a tel
quasi-injective module is quasi-injective. By part 2, either Q is simple which implies that Q = Q or Q = A. Since Q is a left A submodule of Q, then Q = A since A is a field. D If A is not a domain, A ""' K where K is a right Ore domain since A is hereditary. Clearly, K is also a right V-ring satisfying (3) of 5.19. Moreover, since each finitely generated torsion left K-module is semisimple, (2) of 5. 7 is trivially satisfied. Thus, K is also a left V-ring implying that A is likewise. We next consider a fundamental problem in the theory of formal differential (or difference) equations namely the problem of trying to determine when an arbitrary consistent system of homogeneous linear differential equations has a solution in an arbitrary differential ring A. As we shall see, a necessary and sufficient condition for the solvability of any consistent system is that ~AA be an injective module. In particular, when A = k is a field, this is equivalent to !!)k being a V-ring (5.21). Let A be a differential ring (commutative) with derivation () and !!)A the ring of differential polynomials. Each element n
2: a
d =
1 1/) E !!)A
1=0
determines a linear operator on A defined by a~
n
2: a 8 (a) = 1
1
d(a).
1=0
To say that f3
E
im d is equivalent to saying that the n-th order
linear differential equation (l.d.e.) d(x) =
n
.L 1=0
a 181(x) =
f3
has a
solution in A, with ker d = solution space of d(x) = 0. More generally, let d11 E!/)A, i = 1, ... ,m,j = 1, ... ,n and D = (d11 ) E Matmxn(!!}A)· D defines a map (also denoted D)
92
Simple Noetherian rings
as follows:
(Note that we are viewing elements of the as column vectors of length n.)
For
(!j
e A •, there is an
(~A•
..,.,emted
A)-bimodule An
system of linear
differential equations n
2: du(x) =
b1
~ = I, ... , m
(I)
i=l
or more succinctly D(x) =b.
Naturally we would like to know when system (I) has a solution. By a solution to (I) we mean any column vector
G:)
such that
n[(!J] (!J· To that end observe that D induces D*
(ordinary matrix multiplication on the right by D). Here, we have agreed, for functorial reasons, to consider elements of the module ~Am as row vectors having length m. Let C = cok D*. Then
V-rings
93
is exact. Applying the functor hom~ A(-, A) we get (after some obvious identifications) the exact sequence 0 ~ hom~A(C, A)~ An~ Am.
Suppose g E Am = hom~J~Am, A) and D(f) = g for some fE An, that is, f is a solution of the system D(x) = g. Then, clearly, g induces the zero element of hom~A(K, A) where K = ker D*. For 0 ~ K ~~Am~ ~An
lg A
l'
~A
commutes and has exact rows. Finally, let J = {g E Am I g induces the zero element of hom~A(K, A)}. Then, clearly, Jfl::::::: Ext~A(C, A)
where
I = im D.
Thus, we can think of the extensions of A by C, Ext~A(C, A) as obstruction classes to the solvability of D(x) = g, their triviality equivalent to solvability. Similarly, hom~A(C, A) measures the number of different solutions. If Ext~A(C, A) = 0 for all finitely generated left ~A-modules C, then each' consistent system' D(x) = g (g E J) has a solution in A and conversely. This condition is of course equivalent to the injectivity of A. When A = k is a field, k as a left ~k-module is clearly simple and hence, there is an intimate connection between the 'real world' and the injectivity of certain simple modules. The next proposition is a trivial consequence of 3. 7 and will be used in the proof of the main results of this section. 5.20 PROPOSITION Let M, N E ~-mod, MR flat and ~N injective. Then homR(M, N) is an injective differential module. D 5.21 THEOREM Thefollowing are equivalent for~= ~k· (I) ~k is injective; (2) each M E ~-mod which is finite dimensional over k is injective in ~-mod; (3) each linear differential equation has a solution in k.
Simple Noetherian rings
94
Moreover, ~k is the unique simple left £!)-module up to isomorphism iff for each homogeneous l.d.e. has a nontrivial solution ink. Proof (I)~ (3) and (2) ~(I) are clear. (I)~ (2): Let M be finite dimensional and M* = homk(M, k). Clearly, M*k is flat and since ~k is injective, M** is injective in f!}-mod by 5.20. However, since dim kM < oo, M : : : : M** in f!}-mod by 3.8, completing the proof of the equivalence of (1) and (2). Since £!) is a pli-domain, to show that ~k is unique, it suffices to show that hom~(£!) jf!)d,
for all dE£!), d =
n
.L 1=0
k)
=1=
0
a 181• Consider the homogeneous linear
differential equation n
L a 8 (x) = 0 1
1
1=0
and let a be a nontrivial solution. Clearly, the mapf: f!}jf!)d--+ k defined by r + f!)d r-+ r ·a is £!)-linear and nonzero. Conversely, if ~k is unique and
n
.L 1=0
a 181(x) = 0 is an arbitrary
homogeneous linear differential equation, set d
n
=
.L 1=0
a 181 and
let f : £!)f f!)d --+ k be nonzero (f exists since ~k is unique). If (I + f!}d)f = a =1= 0, d(a) = 0 and hence, we have found the desired nontrivial solution of d(x) = 0. D Constructing fields k satisfying condition (3) is quite easy (at least in theory). For example, if k is universal (cf. Cozzens [70]), then condition (3) is trivially satisfied. Thus, we have our first nontrivial examples of simple Noetherian V-domains which are not fields. Note that each cyclic £!)-module, not isomorphic to£!), is injective. This is because such a module is necessarily finite dimensional over k (this also follows from 5.I9(I)). Analogous results hold for partial differential rings (see Cozzens-Johnson [72]). Of course, these rings can have any
95
V-rings
prescribed global dimension. Hence, nontrivial examples of Vdomains exist in all dimensions. A class of simple Noetherian V-domains with similar properties can be constructed via the twisted, finite Laurent polynomials L = LP(k) defined on p. 51. By considering difference n
.L
equations of the form
atpt(x)
b, p the automorphism of k,
=
t=O
we obtain results analogous to Theorem 5.21. We shall refer to this Theorem by 5.21 *.However, in this case, it is quite easy to give rather explicit examples of fields satisfying (3) of 5.21 *. 5.22 ExAMPLE Let k be a field of characteristic p and p : k--+ k be defined by p(a) = aP for all a E k (the Frobenius map). Clearly, pis an automorphism of k, having infinite period whenever k, is, say, separably closed. In this context, linear difference equations are polynomials of the form n
L atXP'
at
E
k.
(2)
t=O
By 5.21 *, if each polynomial of the form n
L atXP' =
b
at, b
E
k,
t=O
has a root ink, then Lis a V-ring. Moreover, in order to have a unique simple £-module, each polynomial of type (2) containing at least two terms must have a nontrivial root in k. By letting k = ZP, these properties are obviously satisfied by algebraic closure of ZP. Recently, Osofsky [71] showed that by suitably modifying the field k in Example l, examples of simple Noetherian V -domains could be obtained with infinitely many nonisomorphic simple modules in contrast to the above example which has only one. In order to make all of this seem plausible, we shall exhibit another interesting property of the ring L which at the same time enables us to precisely determine the number of !-dimensional simple £-modules. Let .9'(1) denote the set of all isomorphism classes of one-
Simple Noetherian rings
96
dimensional (k-dimension, that is) £-modules. If M is onedimensional, (M) will denote the class of M in .9'(1). For M, M' and M" all one dimensional, M ®k M' is an £-module and clearly, dimk(M ®k M') = l. Moreover, it is quite easy to show that M ®k M' : : : : M' ®k M and (M ®k M') ®k M" : : : : M ®k (M' ®k M") as £-modules (of course the £-action is that defined in Chapter 3). Since (k) E .9'(1) and k ®k M : : : : Min £-mod, the operation (M) o (M') = (M ®k M') on .9'(1) is commutative, associative, and has identity (k). Thus, (.9'(1), o) is a commutative monoid. More can be said:
ForME L-mod, M* = homk(M, k)
5.23 PROPOSITION
M* ®k M ~ homk(M, M) as £-modules, where cp is defined by cp(f ® m)[m'] = f(m')m for allfEM*, m, m' EM.
D
It follows immediately from Proposition 5.23 that (.9'(1), o) is in fact, a group if (M) - l is defined to be (M*).
5.24 THEOREM Let k* be the multiplicative group of units of the field k and define cp: k*--+ k* by cp(a) = a- 1 p(a). Then .9'(1) : : : : k*fim cp.
Proof Let (M) E .9'(1) and mE M. Then p(m) = a(m)m for a unique a(m) E k. Since M = km for some mE M, a(f3m)f3m = p(f3m) = p(f3)p(m) = p(f3)a(m)m. Thus, a(f3m) = a(m)mod im cp. Hence, the correspondence (M) r-+ a(m) im cp is a map ifJ: .9'(1)--+ k*fim cp. The verifications that ifJ is a surjective group homomorphism are routine and will be left to the reader. Injectivity of ifl: Suppose (M) E .9'(1), M = km and a(m) im cp = 1/J((M)) = g- 1 p(g) for some g E k. By the above, for each m' EM, a(m') = {3- 1 p(f3) for some f3 E k. Since p(m) can be written in the form f3p(f3) - 1 m, we see that the map M --+ k
97
V-rings
defined by {3m ~ 1 is an L-linElar isomorphism, implying that (M) = (k). D To exhibit a field k where (1) of 5.21 * is satisfied but where Lk is not unique, we proceed as follows. Let q be a prime integer and let k be any field with algebraic closure Tc. Let .fF = { L
I L is a field, k s;; ~
5.25 DEFINITION
L s;; Tc and l E L degree l over k is relatively prime to q} A q-field over k is a maximal element of
.fF.
The utility of q-fields stems from 5.26 PROPOSITION (Osofsky [71]) Let L be a q-jield over k, and let f E L[ X] have degree relatively prime to q. Then f has a root in L. If g E k[X] is irreducible and has degree divisible by q, then g has no root in L. D To obtain the above mentioned example, let k 2 F = Zp(X) be a 2-field, 2 =F p, p : k --+ k defined by a ~ aP and {1r1 I i E w} an infinite set of primes of Zp[X]. Consider the cosets 17-1 = 1r1 im cp and 17- in k*fim cp. We claim that they are distinct. For 1 if 17-1 = 17-1, then 1r11r1 - 1 = aP- 1 for some a E k*. Thus, the polynomial f(Y) = 1r1 YP- 1 - 1r1 has a root in k*. However, by Eisenstein's criterion, f is irreducible over F[ Y] and hence over k[Y] by Proposition 5.26, since k is a 2-field and 2 I deg f. Thus, 17-1 =F 17-1 which implies that the cardinality of (.9'(1)) ~ Xo·
6. PCI-rings
A 'good' theory of ring theory is one which generalizes the Wedderburn-Artin theorems for a ring R with radical N, and a 'good' theory of modules is one which generalizes the basis theorem for abelian groups. In this chapter we are concerned with the latter, in the setting of Dedekind domains, particularly the aspect which states that every finitely generated module M is a direct sum of finitely many ideals and cyclic modules. A 'conceptual' way to effect such a decomposition of M is to notice that M modulo its torsion submodule t(M) is a torsion free module F embeddable in a free module P. Then, the canonical projections of P--+ R induce projections ofF into R which furnish the requisite ideal summands. Moreover, Mft(M) being projective implies that the torsion module t(M) is a summand of M, and the cyclic decomposition for t(M) is a consequence of the fact that R modulo any ideal A # 0 is an Artinian principal ideal ring, hence a uniserial ring over which every module is a direct sum of cyclics (as Kothe [35] showed). Another way to obtain the cyclic decomposition is to observe that every proper cyclic module RJA is an injective RIAmodule. Thus, every cyclic submodule 'of highest order' splits off! We adopt this point of view in this chapter. However, instead of requiring that every proper cyclic right module RfA be injective modulo its annihilator ideal, we make the stronger hypothesis. (right PCI) Every proper cyclic right R-module Cis injective.
Proper cyclic means that C is cyclic but C 1t R. We show that any right PCI-ring is either a semisimple ring, or a simple right semihereditary, right Ore domain. This [ 98 ]
99
POI-rings
reduces the entire theory to the simple right PCI-domains. As we have already observed, such rings occur freely in nature, constituting a broad class of the known simple domains. In order to obtain these results however, we repeatedly use the following characterization of semisimplicity in terms of the class of cyclic modules, namely, 6.1 THEOREM (Osofsky) A ring R is semisimple (Artinian) if and only if each cyclic right R-module is injective. D
Thus, in terms of our development, the limiting case of a PCI-ring (hence V-ring) is a semisimple ring. For a short proof, see Osofsky [68]. Recall that if I is a right ideal of a ring R, then a right ideal K which is maximal in the set of all right ideals Q such that I n Q = 0 is called a complement right ideal, and K is said to be a relative complement of I. In this case, I + K is an essential right ideal of R. Moreover, then, I is a relative complement of K if and only if I is a complement right ideal. In this case, I and K are said to be relative complement right ideals. A ring A is right neat provided that the right singular ideal of A is zero. In this case, the injective hull A of A in mod-A is a right self-injective regular ring containing A as a subring. Moreover, for any right ideal I of A, a unique injective hull1 of I in mod-A is contained in A. Furthermore, 1 is a right ideal of A, generated by an idempotent. Every annihilator right ideal of a right neat ring A is a complement, and every right ideal I of A is contained as an essential submodule in a unique complement 1 which is in fact 1 n A (see R. E. Johnson [51] or Faith [67a]). 6.2 LEMMA If R is a right neat ring, and if I is a right ideal of R, then I is a complement right ideal of R if and only if RJI embeds in R. Proof The complement right ideals of fl are those of the form efl, for some idempotent e E fl, and those of R are of the form eil n R. Thus, if U = eil n R, then the isomorphism
Rjeil n R = RJU::::::: eR
100
Simple Noetherian rings
embeds RJU into eR s;; fl. Conversely, iff: RJU--+ fl, is an embedding, and if f(1 + U) = y, then U = yl. n R. Write fly = fl(1 - e), for some idempotent e. Then yl. = ell, and hence, U = ell n R. D 6.3 THEOREM Let A be a right POI-ring. Then, either A is a regular ring, or else A is a simple ring. Moreover, A is a right V-ring, and every indecomposable in}ective right A-module is either simple or isomorphic to A. Proof By Brown-McCoy [50], A has a maximal regular ideal M, and AJM has no regular ideals ,eO when A # M. If I is any ideal ;60, then every cyclic module C of Afi is a proper cyclic module over A, hence C is an injective module over A, and therefore injective over AJI. Then, 6.1 implies that AJI is semisimple Artinian. Hence, if A is not regular, then M = 0. Since every simple right module is injective, A is a right V-ring, and so by 5.15 a nonzero ideal B contains no right ideal isomorphic to A. Then, for any y # 0 in B, yA is injective, hence a summand of B generated by an idempotent. This implies that B is a regular ideal, contrary to the assumption that M = 0. Thus, A must be simple when A is not regular. If E is an indecomposable injective right A -module, then E = () for any nonzero cyclic submodule C. Thus, if C::::::: A, then E::::::: .A, and if C 1t A, then C is injective, whence E = C is simple. D 6.4 PROPOSITION A right POI-ring A is right neat. Moreover, A has a nonsimple indecomposable in}ective right module E if and only if A is a right Ore domain, not a field. In this case, A is a simple ring. Proof Simple rings and regular rings are right neat, so the first sentence follows from 6.3. Since, by the remarks preceding 6.3, A is a regular ring, then A is indecomposable as a right A-module if and only if A is a field. In this case, A is an integral domain, and A is the right quotient field of A. Since AA is not simple, then A # A. This proves one part of the second sentence, and the converse part is trivial. Then A is either regular or simple by 6.3 and the
POI-rings
101
former can hold only if A is a field. Thus, A is simple in either case. D 6.5 PROPOSITION A right-POI domain R is right semihereditary, that is, each finitely generated right ideal of R is projective. Proof Let P be any nonzero projective right ideal, and let a E R. If C = aR + P is such that C f P : : : : R, then there exists x E R such that x.L = {r E R I ar E P}. Since R is a domain, this would imply that aR n P = 0, and then C = aR E8 P is projective. IfCJP 1t R, then CJP is injective, hence a summand of RJP. Let D be a right ideal of R containing P such that DJP is a summand of RfP complementary to CJP. Then there is an exact sequence 0
--+
P--+ C
E8 D --+ R --+ 0,
since R = C + D, and P = C n D. Thus, C E8 D : : : : R E8 P is projective, and hence C (also D) is projective. An obvious induction on the number of elements required to generate a right ideal shows that any finitely generated right ideal of R is projective, so R is right semihereditary. D The next several results are preparation for the main results stated in Propositions 6.11 and 6.12.
A right ideal A of R is either semisimple, or else A contains an essential right ideal A' of R with A' =F A. Moreover, A' is not a complement right ideal of R. Proof A module is semisimple iff it has no proper essential submodules. Thus, if A is not semisimple, there is an essential submodule A' =F A. Let B be a relative complement of A' in R. If A' were a complement right ideal, then A' would be a relative complement of B, in which case A n B =F 0, and (A n B) n A' = 0 contradicting the essentiality of A' in A. D 6.6
LEMMA
6.7 LEMMA Let I and K be two right ideals of a ring R such that I n K = 0, and I + K is essential. Then, the injective hull of RJI E8 RJK contains fl as a summand. Proof Clearly, RJI E8 RJK contains the direct sum I E8 K,
Simple Noetherian rings
102
which is essential in R, hence the injective hull contains the summand R. D 6.8 PROPOSITION Let R be a right POI-ring. Then, either R is a right Ore domain, or else there is an exact sequence R 2 --+ fl --+ 0, or else R has nonzero right socle. Proof By 6.4, R is a right neat ring, with injective hull fl which is a regular ring containing R as a subring. If every nonzero right ideal of R is essential, then fl is a field, in which case R is a right Ore domain. Otherwise, there are right ideals I and K, neither of which are 0 orR, such that I + K is essential and I n K = 0. If I' and K' are essential submodules of I and K, respectively, then I' + K' is an essential right ideal of R, and by 6.7, the injective hull of Rfl' E8 RJK' contains fl as a summand. Now Rfl' : : : : R would imply that I' is a complement right ideal of R by 6.2. However, by 6.6 I' is a complement right ideal essential in I only if I' = I. Thus, by 6.6 either I or K is semisimple, or else RJI' E8 RJK' is an injective module containing fl as a summand. In the latter case, there is an exact sequence R 2 --+ il-+ 0, as asserted. D A right R-module E is completely injective provided that every factor module EJK is injective.
If R is a right POI regular ring, and if e is an idempotent such that eR is completely injective (e.g., if e is contained in a nonzero idealS # R), then eRe is a semisimple ring, and eR contains a minimal right ideal of R. Proof First, the canonical map eR @ Re --+ eRe is an iso6.9
LEMMA
R
morphism. To see this, let {a1}f= 1 and {b1}r=l be finitely many elements of R such that
n
.L 1=1
ea1b1e = 0. Then:
Henceforth, let Q = eRe, and let M = QJK be a cyclic right Q-module. Since Q is a regular ring along with R, then every
POI-rings
103
Q-module is flat, and therefore the canonical exact sequence 0 --+ K --+ Q --+ M --+ 0 implies exactitude of 0--+ K
0Q eR--+ Q 0Q eR--+ M 0Q eR--+ 0.
Since Q 0 eR ::::; eR as a (Q, R)-bimodule, this implies that Q
C = M
0
eR is an epimorphic image of eR in mod-R, and
Q
hence is injective. (If e is contained in a nonzero idealS # R, then eRJL ::::; R, for some right ideal L, would imply via projectivity of R that eR contains a submodule ::::; R, contrary to 5.15 which states that S contains no right ideals ::::; R. Thus, eR is completely injective in this case.) In order to show that M is injective in mod-Q, it suffices to show that M is isomorphic to a summand of any over-module. Since C = M 0 eR is injective in mod-R, if Y is any right Q
Q-module containing M, then the induced inclusion C--+ Y splits. Write Y
0
eR = C
E8 X,
0
eR
Q
for some right R-module X.
Q
Now, (Y
0Q
eR)
0R
Re::::; (C
0R
Re)
E8 (X 0R
Re).
Since eR 0 Re ::::; Q canonically, it follows that R
C
0R
Re ::::; (M
0Q
eR)
0R
Re ::::; M
0Q
(eR
0R
Re)
::::;M0Q::::;M. Q
Thus, M is isomorphic in mod-Q to a summand of Y::::; ( Y 0 eR) 0 Re and so M, hence every cyclic right Q-module, is Q
R
injective. Then, Q is semisimple. Let I be a minimal right ideal of Q. Since Q is semisimple, I = fQ for an idempotent f E Q, and thenfQf = fRf is a field ::::; EndfQQ. Since R is semiprime, this implies that fR is a minimal right ideal of R contained in eR (Jacobson [64a], p. 65). D 6.10
LEMMA
If R is a right POI-ring, and if Sis any ideal
# 0, R, then S contains any right ideal I for which there is an
Simple Noetherian rings
104
isomorphism f: RJI--+ R. Moreover, I = x.L for x = f(1 + I), and xy = 1, for some y E R. Proof Let f: RJI--+ R be an isomorphism. Then, I = x.L, where x = f(1 + I), and xR = R. Thus, xy = 1 for some y E R. Since every cyclic right RJS-module is injective, then RJS is semisimple Artinian by 6.1. Therefore, every one-sided inverse in RfS is two-sided, and consequently, yx = 1 - s, for somes ES. Thus, if xa = 0, then a= sa ES. This proves that I = x.L is contained inS. D 6.11 PROPOSITION If R is a right POI-ring, and if R is regular, then R is semisimple. Proof Let S denote the intersection of all nonzero ideals of R. The proof falls into three cases: (1) S = 0 but R is not simple. By Lemma 6.10 if Rfi is a cyclic right R-module isomorphic toR, then I is contained in every nonzero ideal of R. Thus, (1) implies that RJI is injective for every right ideal I =1= 0. If R has idempotents e =1= 0, e =1= 1, then RfeR : : : : (1 - e)R is injective, and, similarly, eR is injective, in which case, R = eR E8 (1 - e)R is injective. Thus, every cyclic right R-module is injective, so R is semisimple. (2)
s
=I= 0.
First, RfS is semisimple, since every cyclic RJS-module is injective. Second, by Lemma 6.9 R has nonzero socle. The fact that S = 8 2 is the least ideal of R implies that R is prime, and hence that S is the right socle of R. If V is any minimal right ideal of R, then V is injective, and hence V fl = V is a right ideal of fl, and in fact, V is a simple right ideal of fl. Thus, right socle fl 2 S. Furthermore, if W is a minimal right ideal of fl, then W n R = U is a minimal complement right ideal of R such that W = U fl. But every nonzero right ideal of R contains a minimal right ideal, and the latter is a minimal complement. Thus, U is a minimal right ideal of R, and, as indicated above, U = U fl. Hence, W = U is a minimal right ideal of R. This proves that S = socle fl. Therefore, S is an ideal of fl. If the socle S is finite, then S = R is semisimple, and the proof is complete. Otherwise, S : : : : v for some infinite
POI-rings
105
cardinal a, and hence, there is a right ideal K contained in S such that K::::::: v::::::: S::::::: K 2 • Then, RJK::::::: R would imply that K = eR for an idempotent e E R, in which case K, whence S, is a finite sum of injective simple modules. But this case has just been discarded. Thus, RJK is an injective module containing a submodule K 1 ::::::: S, and hence containing the injective hull R of S. Since R is then a summand of a cyclic module, R is cyclic, and hence there exists x E R such that R = xR. Let a E R be such that xa = l. Since S is an ideal of R, if c E R, and if ac E S, then c = xac E S. This proves that [a + S] is not a left zero divisor in RJS. Since RJS is semisimple, this means that [a + S] is a unit of RJS, with inverse, say [a' + S]. Then, aa' = 1 - s, for somes ES, and
xaa' = x(1 - s) = a'. Thus, x = xs + a'. Since S is an ideal of R, then x E R, and therefore, R = xR s;; R. Since every cyclic module is therefore injective, R is semisimple in this case too. (3) R is simple. This case follows from the next proposition. 6.12 PROPOSITION A simple right POI-ring R is either semisimple, or else a right semihereditary simple domain. Proof Case (1). R contains a nonzero injective right ideal A. Since R is simple, then A is a generator ofmod-R, which implies that R = R and hence, R is semisimple by 6.1. Case (2). If (1) does not hold, then, since every simple module is injective, R has zero right socle. Then, by 6.8, either R is a right Ore domain, or else R 2 --+ R --+ 0 is exact. In the former case, R is right semihereditary by 6.5. Hence, assume: Case (3). R 2 --+ R --+ 0 is exact. Since R has no injective right ideals =F 0, every principal right ideal aR =F 0 is isomorphic to R. Let f: aR--+ R be an isomorphism. Then, f(a) = xis an element of R such that xR = R, and x.L = a.L. Let y E R be such that xy = l. Then, e = yx is idempotent. If e. =F 1, then eR::::::: Rand (1 - e)R::::::: R, hence R::::::: R 2 • This implies that R --+ R--+ 0 is exact and R --+ R E8 R --+ 0 is exact. Since C = R E8 R is thereby cyclic, then C is either injective,
Simple Noetherian rings
106
whence R is injective, or else 0 : : : : R, whence R contains an injective right ideal A : : : : fl. But, in either case, R is semisimple. This proves that e = yx = 1, whence that x.L = a.L = 0 for every nonzero a E R. Then R is an integral domain, which must be simple and right semihereditary by 6.5. D 6.13 THEOREM A right POI-ring R is either semisimple, or a right semihereditary simple domain. Proof By 6.3, R is either regular, whence semisimple by 6.11 or else R is simple, in which case the last proposition applies. D 6.14 PROPOSITION Let R be a right POI-domain which is not right Ore, then: (1) fl is a finitely presented cyclic module. (2) If I is any right ideal, then RJI : : : : fl iff I is a complement right ideal # 0, R. Furthermore, any complement right ideal I is finitely generated (by 3 elements). (3) Any finitely generated torsion right module M is injective, and a-cyclic (that is, a finite direct sum of cyclic modules). (4) If I is a right ideal, then there is a unique least complement i containing I, and i is the unique complement containing I as an essential submodule. Moreover (any finitely generated submodule of) iji is cyclic and injective. (5) If x E fl, and xi R, then xR = fl iff xa = 1 for some a E R. Moreover, in this case, J a = x.L + aR is a finitely generated essential right ideal, and Rf J a ::::::: flj R. Proof of (1) If I is any complement right ideal #0, and if K is the relative complement of I, then K embeds canonically as an essential submodule of RJI. Since RJI is injective, then RJI : : : : 1?., so we must show that K : : : : fl. Now K contains a right ideal aR::::::: R, and hence we have
fl
2
K.
2
(;R : : : : fl,
so by a theorem of Bumby and Osofsky (see Bumby [65]) we have K : : : : fl as desired. This will prove (1), once we complete the proof of (2) showing that I is finitely generated. Proof of (2) Let aR be a nonzero cyclic right ideal which is not essential. Then RfaR is an injective module containing a submodule X::::::: fl. Write RfaR = YfaR E8 X, for some
POI-rings
107
module Y 2 aR. Then, RJY::::::: X::::::: fl, so that Y is a complement right ideal by 6.2. Furthermore, Y faR is cyclic, so that Y = aR + bR, for some b E R, is finitely generated, hence projective. Therefore, fl is finitely presented. If I is any complement right ideal =F 0, R, then RJI : : : : fl, by l. Then Schanuel's lemma implies that R E8 Y::::::: R E8 I, so I is generated by 3 elements. Conversely, if I is a right ideal such that RJI : : : : fl, then I is a complement right ideal by Lemma 6.2. This proves (2).
Proof of (3) If M = a 1 R + ... + anR is finitely generated and torsion, then a 1 R is injective, so M = a 1 R E8 M 1 for some submodule M 1 . Now M 1 is generated by a;, ... , a~, where b' is the image of any b E M under the canonical projection M --+ M 1 . By induction, M 1 , hence M, is a direct sum of finitely many injective cyclic modules. Therefore, M is injective. Proof of (4) By the remarks preceding 6.2, in any right neat ring R, any right ideal has just one injective hull! (=maximal essential extension) contained in fl. Then i = 1 n R is the unique complement containing I as an essential submodule. Moreover, since any least complement containing I is essential over I, then i is the unique least complement containing I. Any finitely generated submodule of ifI is injective by (3), hence a summand of RJI, and therefore cyclic. Proof of (5) If xR = fl, then 3a E R with xa = l. Conversely, if xa = l with x E fl, a E R, x ¢; R, then x.L =F 0 since x(l - ax) = 0. Thus, xR : : : : Rfx.L is a proper cyclic, therefore injective. But xR 2 R and therefore xR = fl. Let J = {r E R I xr E R}. Clearly, xJ = R, and there is a (canonical) isomorphism xRfxJ : : : : RjJ (sending [xr + xJ] r-+ r + J, 'r/r E R). Since xR = fl, we have the desired isomorphism iljR::::::: RfJa provided we show that J coincides with Ja = x.L + aR. Clearly J 2 x.L + aR. Moreover, if y E J, y = (y - axy) + axy and y - axy E x 1 , axy E aR which shows that J = x.L + aR = Ja. D Following from 6.14(3), we have a theorem reminiscent of the situation for hereditary Noetherian prime rings and Dedekind rings (cf. Kaplansky [52], Levy [63]).
Simple Noetherian rings
108
6.15 CoROLLARY If R is a right POI, right Ore domain, then every finitely generated right ideal is projective and generated by two elements. Furthermore assuming that R is left Ore, then any finitely generated module M is a direct sum of a finite number of right ideals of R, and cyclic injective modules. Proof Over a two-sided Ore domain, any finitely generated torsion free module F is embeddable in a free module of finite rank (see 2.36). Thus, since R is semihereditary by 6.5, F = Mft(M) is projective, so the canonical map M--+ F splits. Thus, M : : : : F E8 t(M). Moreover, F is isomorphic to a direct sum of right ideals. Finally, the proof of 6.14(3) suffices to establish that t(M) is a-cyclic, and injective. In particular, if I is any finitely generated right ideal, and if a is any nonzero element of I, then I faR, being finitely generated torsion, is injective, and, being a summand of RfaR, is therefore cyclic. Thus, I = bR + aR for some b E R. D The proof of 6.14(2) has the corollary: 6.16 CoROLLARY If R is a right neat ring, and if I is a right ideal such that fl embeds in Rfl, then there exists an element bE R such that Y = bR + I is a complement right ideal of R. D 6.17 THEOREM A right POI-domain is right Ore. Proof If R is not right Ore, then we may assume that fl : : : : Rfl is a finitely presented cyclic module by 6.14(1), that is, that I is finitely generated. Write 0--+ I--+ R--+ il--+ 0
(1)
exact. Now, any finitely generated left R-submodule M of fl can be embedded in R (via a right multiplication by a nonzero element of R), and so fl is a direct limit of projective modules, whence fl is a flat left R-module (all of which is well-known; e.g., Sandomierski [68]). Thus, we have exactness of 0 --+ I
0
il--+ R
0
il--+ il0 il--+ 0.
(2)
Since fl is left flat, and I is finitely generated, then I
0 fl : : : : I fl
R
R
R
R
is a finitely generated right ideal of fl, which by the remark in the proof of 6.14(1) is isomorphic to fl, whence a summand of fl.
109
POI-rings
This proves that flQ9 fl is isomorphic to a summand of fl, R
whence has zero singular submodule on the right. Now the kernel of the canonical map flQ9 il--+ fl is contained in the R
singular submodule, hence must equal 0. This proves that the embedding of R into fl is a ring epic (Silver [67]). This, together with left flatness of fl, suffices to show that a right fl-module M is injective as a right fl-module iff it is injective as a right R-module. In particular, if M is a proper cyclic right fl-module, we conclude that M is injective, since M is a proper cyclic right R-module. Then, by Osofsky's theorem, fl is semisimple, which can happen iff R is a field. This proves that R is right Ore. D It is an open question whether or not a right PCI-domain R is right Noetherian. If it is, then every injective right module M is ~-injective in the sense that any direct sum of copies of M is injective. It is known that to test for ~-injectivity of M it suffices to test injectivity of M
The proof has the corollary.
llO
Simple Noetherian rings
6.19 CoROLLARY If R is a right POI -ring, and if R is not right Noetherian, then there is a cyclic injective right R-module E with infinite essential socle. Proof By 6.13, R must be a domain, not a field. By 5.2, not every semisimple module is injective. Hence, there is a semisimple module M with M not semisimple, hence containing a cyclic submodule xR which is not semisimple. Then, xR has infinite socle, since any finite direct sum of simple modules is injective. Moreover, since R is not a field, soc R = 0, so xR ~ R, that is, xR is injective. D 6.20 PROPOSITION Let R be a right POI-ring, let I be a finitely generated essential right ideal, and let E = RJI. Then, B = EndER is a right self-injective regular ring. Proof It is clear that E is completely injective. If b E B, thenO = bEisinjective,henceasummansfofE. WriteO = XJI for a right ideal X, and let YJI be the complementary summand of E. Then YJI is cyclic, so Y is finitely generated. This implies that 0::::::: RJY is finitely presented. If kerb = KJI, then there is an exact sequence 0--+ K --+ R --+ 0--+ 0, hence by Schanuel's lemma, K is finitely generated. But, by induction, every finitely generated submodule of E is injective. Thus, ker b is essential only if b = 0. By Utumi's theorem (Appendix 1), this proves the proposition. D 6.21 CoROLLARY Let R be a right POI-domain, with a unique simple right R-module V. Assume that R is not right Noetherian, and let I be the right ideal given by 6.19 such that E = RJI is injective with infinite essential socle. Then I is not finitely generated. Proof E = RJI is not semisimple, hence there exists a maximal right ideal M 2 I such that MJI contains the socle of RJI. The socle S of E : : : : direct sum of copies of V, so there exists a nonzero map RJM--+ E. Thus, MJI is an essential submodule of RJI, and is the kernel of an endomorphism f of E. Then,fis contained in the radical of EndER, so the preceding proposition shows that I cannot be finitely generated. D
POI-rings
Ill
Since B = EndER has nonzero radical J, and BjJ::::::: End SR, BjJ is a full right linear ring. 6.22 DEFINITION A ring R is a right fir provided that every right ideal of R is a free module, and every free right module has invariant basis number (IBN). Thus, an isomorphism ff- 1> ::::::: U-J), for sets I and J, implies card I = card J. 6.23 COROLLARY A right POI-domain R is a principal right ideal domain iff R is a right fir. Proof Any right fir which is also right Ore is necessarily a pri-ring. For if I is any right ideal generated by a 1 and a 2 , a 1 ¢; a 2 R, then since a 1 R n a 2 R # 0, a 1 x = a 2 y # Oforx, y E R. Hence, we obtain a nontrivial linear relation in I, namely a 1 x + a 2 ( - y) = 0 contradicting freeness of I. So, I = a 2 R. The proof of the corollary is now clear. D 6.24 PROPOSI'l'ION If R is a right Noetherian right POIdomain with right quotient field Q # R, then R is right hereditary and (1) QJR is semisimple; (2) R embeds canonically in End QJR under a map: r r-+ r', where r' sends [x + R] r-+ [rx + R]; (3) for any right ideal I, the factor module RJI is a semisimple module of finite length; (4) any finitely generated torsion module is semisimple of finite length. Proof A right PCI-domain R is right semihereditary by 6.5, and hence Noetherian implies right hereditary. (1) The module QJR is a torsion module, and by 6.14(3) every finitely generated torsion module is injective. Since R is right Noetherian, this implies that for any finitely generated submodule M ofQJR, every submodule is a summand, and hence that M is semisimple. It readily follows that QJR is semisimple. (2) Obvious. (Note that since R is simple, and the map is nonzero, the map is an embedding.) Proofs of (3) and (4) are similar to that of (1) (cf. 6.14(3).
D
Simple Noetherian rings
ll2
6.25 THEOREM A left Ore right Noetherian right POIdomain is left Noetherian. Proof Let (3)
be an ascending chain of finitely generated (hence projective) left ideals of R, c E I 1 and D, the 2-sided quotient field of R. The set It - 1 = {dE D I ltd s;; R}
is a right R-submodule of D, canonically isomorphic to It* = homR(It, R) since Rlt is essential. By applying ( ) - 1 to (3) we obtain (Rc)- 1 2 1 1 -
1
212 -
1
2 ... 2
R.
Since (Rc) - 1 = c - 1 R, multiplication by c yields R 2 cl 1 -
1
2 cl 2 -
1
2 ... 2 cR.
By 6.24(3), RfcR is Artinian. Thus for some n > 0, cl n- 1 = cln+i- 1 for all j ~ 1 and hence In - 1 = In+i- 1 • However, In - 1 - 1 = In for all n by projectivity of In and hence, In = In+i for all j ~ 1. Thus, chain (3) terminates in finitely many steps.
D 6.26 THEOREM (Boyle [74]) A right and left Noetherian ring R is a right POI-ring iff R is a right hereditary right V-domain. Furthermore, in this case, R is a left POI -domain. Proof Since a two-sided Noetherian, right hereditary ring is left hereditary, (Jans [64], p. 58), the first statement follows trivially from 5.19(1). By 6.24(4), each finitely generated torsion right R-module is semisimple and hence, each finitely generated torsion left R-module is semisimple by 2.32. Consequently, each left ideal is a (finite) intersection of maximal left ideals. Thus, R is a left V -domain and hence, a left POIdomain by 5.19.1. D
7. Open problems
Let A = End 8 U be a simple right Goldie ring, with U A a uniform right ideal finitely generated projective and faithful over the right Ore domain B, with T = trace 8 U a least ideal of B. (Some of these requirements are redundant.) (1) Is A similar to a domain R?
This can happen iff A contains a (finitely generated) projective uniform right ideal W. (2) Is A ::::; Rna full n x n matrix ring over a domain R?
Clearly yes to (2) implies yes to (1). (3) Does A have nontrivial idempotents when A is not a domain?
If e = e2 E A is nontrivial, then eA is a (B, A)-progenerator, where B = eAe ::::; End eAA- Suppose that (3) has an affirmative answer. Since B has Goldie dimension less than that of A, an induction on the Goldie dimension shows that there exists e E A such that B = eAe is a domain. Then A is similar to a domain, since eA is a (B, A)-progenerator. Thus, yes to (3) implies yes to (1). (Note added in proof: A. Zalesski has announced an example giving a negative answer.) (4) Let R be a right Ore domain with a finitely generated projective left module W such that T = trace R W is a least ideal of R. Can W be chosen such that W is indecomposable of rank > 1 ? (The rank of W is defined to be to the dimension over D of the left vector space D@ W, where D is the right quotient field R
of R.) (5) If R is a simple right Ore domain, is every finitely generated projective left R-module W a direct sum of modules of rank 1 ? [ 113 ]
Simple Noetherian rings
114
By induction on the ranks, one can see that the answer to (5) is yes iff that to (4) is no for simple R. (In this case traceR W = R for every W.) Moreover, yes for (5) holds iff yes to (3) holds. (6) Assume that the answer to (2) is yes, and let B be a simple right Ore domain. If W is any finitely generated projective module over B, then there exists a projective module U of rank lover B, and an isomorphism W::::; Un, for some integer n ~ l. For then Rn = A = End 8 W is a simple right Goldie ring, and U = We 11 has the desired property, where e11 is the matrix unit of Rn (in the usual notation). Clearly U has rank l because End 8 U::::; e11 Ae 11 ::::; R is right Ore domain. Moreover
w = L Weu::::;
Weu
®· .. E8
Weu ::::;
un.
I= 1
(7) Does there exist a right V-domain with a prescribed (finite) number of simple right modules? In Chapter 5, we presented Cozzens' examples of simple V-domains, each having a unique simple module (on either side). We also constructed Osofsky's example of a V-domain with countably many simple modules. But so far we have neither an example of a right V-domain which is not a left Ore domain, nor one having a finite number n of simple modules for any n>l.
(8) Determine new examples of simple Noetherian (domains) rings unlike those described in Chapter 3. (9) Is the ultraproduct (defined presently) of countably many copies of a simple Noetherian V-domain such as that described in Chapter 5 necessarily a V-domain? a POI-domain? Recall that a filter .fF of subsets of a set I is a family of subsets of I satisfying (a) 0, the empty set, is not in .fF, (b) 81,82 E.fF ~ 81 (") 82 E.fF, (c) SE.fF,S s;;; T s;;; I~ TE.fF.
An ultrafilter is defined to be a maximal filter which obviously exists by Zorn's lemma.
Open problems Suppose {Ra : a E
ll5
I} is a family of rings and R
n
Ra = ael Ra'rla}. If .fF is any ffiter on I, we =
{!If: I--+ U Ra and f(a) E ael define f = g(mod .fF) iff {a I f(a) = g(a)} E .fF. Clearly, 1 = {! E R If =O(mod .fF)} is a two-sided ideal of R. The factor
ring Rji is usually denoted
n Raf.tF and is called an ultraael
product whenever .fF is an ultrafilter.
It is known that ultraproducts preserve certain properties of the rings Ra, namely, those which can be described by first order statements (see, e.g., Robinson [63]). For example, the properties of being a domain, a field, an Ore domain, semihereditary are all first order properties; being Noetherian and hereditary however, are not first order properties. If Ra is the domain described above for all a E w, set U = nRaf~ U is necessarily a non-Noetherian, semihereditary Ore domain. Moreover, U is simple since the following first order property, equivalent to simplicity, holds in each Ra: 'r/a E Ra, 3x, y E Ra such that
xa+ay=l. Find an example of a right Noetherian right V-(PCI-) domain which is not a left V-(PCI-) domain. Here is a possible method for generating the desired nonsymmetric examples. Let () be a p-derivation of a noncommutative field k with p-nonsurjective. Extend 8(p) to a field Tc ::::> k in such a manner that (a) every linear differential equation in () has a solution in Tc, (b) p is still nonsurjective. Clearly, if this is possible, the ring of p-differential operators with coefficients in Tc will be the desired one-sided example (see Theorem 5.21). (10)
(ll)
Find an example of a non-Noetherian POI-domain.
(12) Find a left Noetherian right Ore domain which is not right Noetherian (see example 2, Chapter 4).
Simple Noetherian rings
116
(13) Is the tensor product of two simple V-rings A ®c B over the center C of A necessarily a V -ring, e.g., is it true for fields? e.g., if D is a field with center C, is D ®c C(X) a V-ring? (If DJC is an algebraic algebra, then D ®c C(X) is a field whenever D[X] = D ®c G[X] is not a primitive ring.)
A ring R is a right QI-ring if every quasi-injective right Rmodule is injective. The examples of Noetherian V-rings of Cozzens [70] are all QI-rings, and principal (right and left) ideal domains. (See Chapter 5.) These domains are thus hereditary. Boyle [74] proved that Noetherian hereditary V-rings are QI, and conjectured that every right QI-ring is right hereditary. Now a theorem of Webber [70] as generalized by Chatters [71] states that any (2-sided) Noetherian hereditary ring satisfies the restricted right minimum condition, RRM: R satisfies the d.c.c. on right ideals containing any essential right ideal. Thus, for (right and left) QI-rings, RRM is a necessary condition for the truth of Boyle's conjecture. A ring R has right Krull dimension K -dim ~ 1 if each properly descending chain Al
::::>
A2
::::> ••• ::::>
An
::::>
of right ideals of R, such that for each i = 1, 2, . . . the right R-module AtfA1 + 1 is not Artinian, has only finitely many terms. A structure theorem of Michler-Villamayor [73] classifies right V-rings of right Krull dimension (K-dim) ~ 1 as finite products of matrix rings over right Noetherian, right hereditary simple domains, each of which are restricted semisimple. These rings are thus right hereditary, verifying Boyle's conjecture for these rings and in particular for RRM-rings. This introduces the problem: (14)
Prove Ann Boyle's conjecture.
For an extension of the Michler-Villamayor result, using different methods, consult Faith [74b], who proves that any right QI simple but nonsemisimple ring R possesses an injective non-
Open problems
117
simple indecomposable right module E such that every factor module of any direct sum of copies of E is injective, and any proper factor module of E is semisimple. Moreover, if every nonsimple indecomposable injective right module E has this property, then R is right hereditary (Faith [74b]). A right QIring has the property that the endomorphism ring of an indecomposable injective module is a field. This property for a right Noetherian ring has been characterized by Faith [74a].
Afterword
The most important class of simple rings is the category of fields, denoted FIELDS. These are the rings in which every nonzero element is a unit, and, like the quaternions, may be noncommutative. They have also been called division rings, but we retain this terminology only if R is a finite dimensional algebra over its center, in which case we say division algebra. The literature on division algebras is vast, and we refer the reader either to Albert [39], or to Deuring [48] for an account up to about 1936. Recently, Amitsur [72] solved the question of the existence of division algebras which are not crossed products in the negative, so the reader may refer to this paper for new perspectives.
Steinitz extensions Steinitz [48] determined that any commutative field F can be obtained as an extension of the prime subfield P by two intermediate extensions: first, a purely transcendental extension TfP (meaning that Tis generated by a set {x1} 1e 1 of elements any finite subset of which generates a rational function field over Pin those variables); second, F is an algebraic extension of T in the sense that every element y E F satisfies a nonzero polynomial overT. Cartan-Brauer-Hua Unfortunately, a Steinitzian simplicity cannot hold for a noncommutative field F, since a very elementary theorem, the Cartan-Brauer-Hua theorem (see Jacobson [64a]), implies that F is generated as a field by the conjugates of any noncentral subset. Therefore, if some element y of F is transcendental, that is, not algebraic, over its center, then F is generated by [ 118 ]
Afterword
ll9
{x- 1yx}xeF*• where F* denotes the units group ofF, so F is
then generated by transcendental elements. Similarly, ifF is not purely transcendental, that is, if some noncentral element y of F is algebraic over its center, then F is generated by the conjugates of y, hence by algebraic elements! If, as we have indicated, the category FIELDS admits no quick classification in either of the two classical modes, i.e., the classification of all rational division algebras as 'cyclic division algebras' as introduced by L. E. Dickson, or in Steinitzian style, then how can we expect a rapid purview of the much larger class of simple rings? VVedderburn-~in
Of course, great simplifications are possible if we choose the Wedderburn-Artin gambit: any simple ring R with descending chain condition on right ideals, that is, any simple right Artinian ring, is a full n x n matrix ring Dn over a uniquely determined field D. This 'reduces' the structure of R to that of an 'underlying' field (i.e., forget the field!). The power of the Wedderburn-Artin theorem lies in the fact that the structure of any module over a semisimple ring is transparent, namely, a direct sum of simple modules. This fact makes it the fundamental tool in the structure of right Artinian rings, since if J denotes the radical of such a ring R, then any RfJ-module, e.g., JfJ 2 , is semisimple. In contrast, the existence of so many types of simple Lie algebras causes the proofs of many theorems on Lie algebras to devolve into seemingly countless special cases. Thus, while the variety of simple Lie algebras lends interest to the subject, the application of their structures makes the ensuing mathematics more boring! The same observation can be made about the structure theory of simple rings inasmuch as there are many seemingly different, i.e., nonisomorphic types, and, as we have shown, module theory over them is quite complex even for the most explicit types of simple rings. The magnitude of the task of classifying simple rings is the raison d'etre of this volume. While primitive rings and prime
120
Simple Noetherian rings
rings have evolved as fntitful generalizations of simple rings, and (in the latter case) of integral domains, there are just too many to classify. At present, the determination of the structure of simple rings with ascending chain conditions offers challenges enough to occupy the talents of mathematicians in the foreseeable future. (See Open Problems, Chapter 7.)
Appendix
I. Homological dimension If ME mod-R, a projective resolution forM, P(M), is an exact sequence
· · .--+ Pn--+ Pn-1 --+. · .--+ P1--+ Po--+ M--+ 0, where each P 1 is projective. Clearly, each module has a projective resolution. If P 1 = 0, Vi ~ n + l, we say that P(M) has length n. The greatest lower bound of the lengths over all projective resolutions for M R is called the projective or homological dimension of M R and is denoted pd M R, pd M or hd M. By a trivial extension of Schanuel's lemma, one can show that ifpd M =nand 0--+ K--+ Pn_ 1 --+ ... --+ P 0 --+ M--+ 0 is exact with P 1 projective for all i then K is projective. sup{pd M I ME mod-R}is called the right global dimension of R and will be denoted r.gl.dim R. The Auslander global dimension theorem reduces the computation of r.gl.dim R to that of the projective dimensions of the right ideals. THEOREM (Auslander)
If R is not a semisimple ring, then
r.gl.dim R = sup{pd I
II
a right ideal}+ l.
If M and Care any two R-modules and 0--+ K 0 is exact with P projective, then
-4. P 4 M--+
0--+ homR(M, C)~ homR(P, C)~ homR(K, C) --+ cok f* --+ 0 is exact. cokf* is usually denoted ExtR 1 (M, C). ExtR 1 (M, C) is a functor: mod-R "-" Ab, contravariant in the first variable and covariant in the second. Moreover ExtR 1 (M, C) = 0 VC(VM) iff M is projective (Cis injective). (See Lambek [66] or CartanEilenberg [56].) [ 121 ]
122
Simple Noetherian rings
Flat Modules and Regular Rings PROPOSITION AND DEFINITION A module MR is called flat if it satisfies any of the following equivalent properties: (l) M ®R (- ): R-mod "-" Ab is an exact functor; (2) for all (finitely generated) left ideals of R,
M ® Jc~n MI where the canonical map is the one induced by M ® I -. M ® R =M. PROPOSITION AND DEFINITION R is called (Von Neumann) regular if R satisfies any of the following equivalent properties: (l) each ME mod-R is flat; (2) each finitely generated right ideal of R is generated by an idempotent; (3) 'r/a E R, 3x E R such that axa = a. UTUMI'S THEOREM (Utumi [56]) Let MR be injective, A = End M R and N, the ideal of A consisting of all ,\ E A satisfying M V ker ,\. Then (l) AfN is regular; (2) N = rad A.
2. Categories, functors and natural equivalences A category G consists of a class of objects obj G; for each ordered pair of objects, (A, B), a set Mora(A, B), called the morphisms or maps from A to B; and for each ordered triple of objects, (A, B, C), a map (called composition) Mora(B, C) x Mora(A, B)-. Mora(A, C)
satisfying (l) Mora(A, B) fl Mora(A', B') =F 0 iff A = A' and B = B'; (2) eachf E Mora(A, B) has a left identity in Mora(B, B) and a right identity in Mora(A, A);
(3) composition is associative.
Appendix
123
mod-R where objects are right R-modules and maps, R-linear homomorphisms. ExAMPLE
A map f from A f: A---+ B.
to B will be denoted by the standard symbol
A map f: A---+ B is called an equivalence if there exists g: B---+ A such that fg = 1 8 and gf = lA. (Of course, fg is the composition off and g and 18 is the (necessarily unique) left identity for f). Let G and G' be categories. A (contravariant) covariant functor T: G "-" G' is a rule associating with each A E G, an object T(A) E G', and for each mapf: A---+ B, a map T(f): T(A) ---+ T(B). (T(f): T(B)---+ T(A)) satisfying (l) T(lA) = lT(A)• VA E G; (2) T(fg) = T(f)T(g), Vf, g,
(T(fg) = T(g)T(f), Vf, g). VA E G, we have two functors (l) Mora(A, -): G "-"SETS, (2) Mora(-, A): G "-"SETS, defined as homR(A, -) and homR(-, A) respectively. (l) is a ExAMPLE
covariant functor and (2) is a contravariant functor. The unadorned term functor means covariant functor. Two functors S, T : G "-" G' are said to be naturally equivalent, S ::::= T, iffor each A E G there exists an equivalence "Y/A: S(A)---+ T(A) such that for allf: A---+ B the diagram S(A) ~ T(A)
!S(f)
!T(/)
S(B) ~ T(B)
commutes. We call a covariant functor T : G "-" G' an equivalence if there exists S: G' "-" G such that To S ::::= la· and So T ::::= la. In this case, we say that G and G' are equivalent and indicate this by G::::; G'. Finally, a functor T: G "-" G' is called a left adjoint for
124
Simple Noetherian rings
S: G' "-" G if VA E G, Mora-(T(A), ) :::::: Mora(A, S( )) and similarly for the other variable. ExAMPLE If G = mod-A, G' = mod-B, and N, an (A, B)bimodule, then T = ®ANistheleftadjointforS = hom 8 (N, ).
Notes
Chapters 1 and 2
The Introduction indicates a brief history of the subject of non-Artinian simple Noetherian rings, introduced by the Goldie and Lesieur-Croisot Theorems in 1958-60. The Noetherian chain conditions themselves were introduced by Noether in 1921 in carrying over results and techniques of algebraic number theory and algebraic geometry to commutative rings satisfying the ascending chain condition (thus, Noetherian rings). In 1927, Artin generalized some of the Wedderburn Theorems for finite dimensional algebras to noncommutative rings satisfying the (ascending and) descending chain conditions for right ideals. (Later, Hopkins and Levitzki, independently, in 1939, showed that the descending chain condition implies the ascending chain condition, that is, they proved that right Artinian rings are right Noetherian.) In view of the historical aspect of the Introduction, and ad hoc references to key theorems in Chapters 1 and 2, further comments may seem uncalled for. Nevertheless, we have not mentioned the Popesco-Gabriel [64] Theorem which states that for any abelian category C with generator U and exact direct limits, there is a full embedding Homc(U, ) : C "-" mod-B where B = End cU, with exact left adjoint S. This very general theorem provides additional insight for the correspondence theorem for projective modules of Faith [72a] (see 1.13), one of the main tools used in obtaining the structure of simple Noetherian rings given in Chapter 2. To wit, the adjoint functor S induces a category equivalence C : : : : mod-BJK where K = ker S = {X I S(X) = 0}, and mod-BJK is the Gabriel-Grothendieck quotient category (defined in Gabriel [62]). Thus, C is a 'localization' of mod-B in the sense of Gabriel [62], or a 'torsion theory' of mod-Bin the sense of Lambek [71]. [ 125 ]
126
Simple Noetherian rings
It is clear that this can be applied to a simple ring A with uniform right ideal U, since U is a generator ofC = mod-A. In this case, as we have indicated in the Introduction and elsewhere, B = End cU is a right Ore domain, and thus the category mod-A is a quotient category of mod-B. Moreover, the functor Homc(U, ) : C "-" mod-B is a full embedding.
Chapter 3
The best known example of a non-Artinian simple Noetherian domain is what is called the 'algebra of quantum mechanics' or the Jordan-Weyl-Littlewood algebra A 1 • The first systematic study of this algebra which we have found appears in Littlewood [33]. Here, a laborious construction of a quotient field for A 1 is given, anticipating Ore's more general results. Independently, Ore [31, 33] introduced the general ring of skew polynomials k[t; p, 8], established its Euclidean-like properties, and gave the general construction of a classical quotient field for an arbitrary Ore domain. Subsequently, Hirsch [37] generalized some of the Littlewood algebras to 2n generators, providing necessary and sufficient conditions for their simplicity. Twenty-five years later, Rinehart [62] showed that r.gl.dim A 1 = l and in general, r.gl.dim An ~ 2n - l whenever the characteristic of k equals 0; r.gl.dim An = 2n otherwise. Here, An is the ring of linear differential operators in of8X 1 , ••• , ofoXn, over the partial differential ring k[X 1 , ••• , Xn]· Roos [72] has shown that r.gl.dim An = n if the characteristic of k equals 0, settling a special case of a problem posed in Rinehart's paper. Rinehart also showed that these rings can arise in a different algebraic setting, namely, as certain quotients of the universal enveloping algebra of a finite dimensional abelian Lie algebra. In the same direction and attesting to the ubiquity of simple Noetherian rings, Dixmier [63] has shown that if g is a finite dimensional nilpotent Lie algebra over an uncountable, algebraically closed field of characteristic 0, and I is an ideal of the
Notu
127
universal enveloping algebra A of g, then Afl : : : : Am for some m > 0, if and only if I is maximal (see also Cohn [61b]). The necessity of 3.2 (for the case of simple R) appears in Amitsur [57]; the necessity of 3.2(a) is implicit in Hart [71]. Also 3.3- 3.5 are the Krull dimension 1 case of more general results due to Hart (same paper). 3.6(d)-(/) are due to Webber [70]. Finally, the generalities on differential modules are due to J. L. Johnson [71]. Chapter 4 The Goldie and Faith-Utumi Theorems place any simple Noetherian ring R between Fn and Dn where F is a right Ore domain with right quotient field D, and nan integer ;;::: l. This matrix representation has the following drawback: R may properly contain Fn, since in general, F is only a ring-l. The precise relationship between R and F is unknown. For example, does there exist a maximal order F of D such that F n 4 R 1 And if so, are any two of them equivalent right orders 1 Let M denote the n x n matrix units of Dn, let A = {r E R I r M s;; R}, and B = {r E R I Mr s;; R}. Then, as we have shown in the Faith-Utumi theorem, U = B () D = A fl Dis an ideal of P = R () D, and Pn, Un, Un 2 are right orders equivalent to R. Moreover, the proof shows that P, U, and U2 are equivalent right orders of D. Thus far we have not needed the assumption that R is simple, that is, the above holds for any right order R in Dn· However, when R is simple, then a theorem of Faith [65] states that B, A, BA, and U 2 are all simple rings, that is, Fin the FaithUtumi theorem can be chosen to be a simple ring- I. In this case it is easy to see that R is then right Noetherian iff F satisfies the a.c.c. on idempotent right ideals. It would be interesting to know if F can be chosen to be unique up to equivalence of orders. In representing a simple Noetherian ring A = End 8 U, the cut down lemma enables one to choose an Ore domain B with at most 1 nontrivial ideal but then, unlike A, B may not be a maximal order in its quotient ring. On the other hand,
128
Simple Noetherian rings
by the maximal order theorem, we can choose U and B so that B is a maximal order but then B, unlike A, may have an infinite ideal lattice. What properties other than maximality which are inherited when A is simple and Noetherian, is an interesting question which deserves further exploration. We should also point out that the results in the section on maximal orders bear striking similarity to those for maximal orders in the classical sense (see Auslander-Goldman [60] and Ramras [69], [71 ]).
Chapters 5 and 6 Michler-Villamayor [73] have characterized right V-rings having right Krull dimension ~ 1 (that is, right V -rings R such that Rfl is Artinian for all essential right ideals /) as rings similat" to finite products of rings, each of which is a matrix algebra over a right Noetherian PCI-domain. (The theorem is also a consequence of techniques used repeatedly in Chapters 5 and 6.) Goodearl [72] showed that if every proper cyclic right Rmodule is semisimple, then R is right hereditary and a finite product of simple rings (etc.), reminiscent of the original constructions of Cozzens [70]. The observation that the solvability of systems of linear differential equations and the extensions of the base field are intimately connected, is due to Malgrange [66]. The present discussion, as well as (1) ~ (2) of 5.21 and its elegant proof, are due to J. Johnson. (The original proof of the remaining implications given in Cozzens [70] is more complicated.) q-fields were invented by Osofsky to produce examples of Vdomains (PCI-domains) with infinitely many nonisomorphic simples (see Osofsky [71 ]). The example following 5.26 is taken directly from that paper. Most of Chapter 6 is taken from Faith [73b ], and generalizes the results of Boyle [74] (see 6.26) to non-Noetherian PCI-rings.
Reforences
Albert, A. A. (1939) Structure of Algebras, Amer. Math. Soc. Colloq. Publ., Vol. 24, Providence, R.I. Amitsur, S. A. (1957) Derivations in Simple rings, Proc. Lond. Math. Soc. (3), 7, 87-112. Amitsur, S. A. (1972) On central division algebras, Israel J. Math. 12, 408-20. Artin, E. (1927) Ziir Theorie der hyperkomplexen Za.hlen, Abh. Math. Sem. Univ. Hamburg 5, 251-60. Auslander, M. & Goldman, 0. (1960) Maximal orders, TranB. Amer. Math. Soc. 97 (1), 1-24. Bass, H. (1960) Finitistic dimension and a. homological generalization of semiprimary rings, TranB. Amer. Math. Soc. 95, 466-88. Bass, H. (1962) The Morita Theorems, Mathematics Department, University of Oregon, Eugene. Boyle, A. K. (1974) Hereditary QI-rings, Trans. Amer. Math. Soc. 192, 115-20. Brown, B. & McCoy, N.H. (1950) The maximal regular ideal of a. ring, Proc. Amer. Math. Soc. 1, 165-71. Bumby, R. (1965) Modules which are isomorphic to submodules of each other, Arch. Math. 16, 184-5. Camillo, V. & Cozzens, J. H. (1973) A.theorem on Noetherian hereditary rings, Pacific J. Math. 45, 35-41. Ca.rta.n, H. & Eilenberg, S. (1956) Homological Algebra, Princeton Univ. Press, Princeton. Chatters, A. W. (1971) The restricted minimum condition in Noetherian hereditary rings, J. Lond. Math. Soc. (2) 4, 83-7. Cheva.lley, C. (1936) L'a.rithmetique dans les algebres de matrices, Actualitea Sci. Induat., No. 323, Paris. Cohn, P. M. ( 1961a) Quadratic extensions of skew fields, Proc. Lond. Math. Soc. (3), 11, 531-56. Cohn, P.M. (1961b) On the imbedding of rings in skew fields, Proc. Lond. Math. Soc. (3), 11, 511-30. Cozzens, J. H. (1970) Homological properties of the ring of differential polynomials, B1
130
References
Faith, C. (1964) Noetherian simple rings, Bull. Amer. Math. Soc. 70, 730-1. Faith, C. (1965) Orders in simple Artinia.n rings, Trana. Amer. Math. Soc. 114, 61-5. Faith, C. (1966) Rings with ascending chain condition on annihilators, Nagoya Math. J. 27 (1), 179-91. Faith, C. (1967a) Lectures on Injective Modules and Quotient Rings, Lecture Notes in Mathematics, Springer-Verlag, New York-Berlin. Faith, C. (1967b) A general Wedderburn theorem, Bull. Amer. Math. Soc. 73, 65-7. Faith, C. (1971) Orders in semiloca.l rings, Bull. Amer. Math. Soc. 77, 960-2. Faith, C. (1972a) A correspondence theorem for projective modules, and the structure of simple Noetherian rings (in Proceedings of the Conference on Associative Algebras, Nov. 1970), Inatitute Nazionale di Alta Matematica, Sympoaium Matematica, 8, 309--45. Faith, C. (1972b) Modules finite over endomorphism ring, Proceedings of the Tulane University Symposium in Ring Theory, New Orleana, 1971, Lecture Notes in Mathematics No. 246, pp. 145-90, Springer-Verlag, New YorkBerlin. Faith, C. (1973a) Algebra: Rings, Modules and Categories, Springer-Verlag, New York-Berlin. Faith, C. (1973b) When are cyclics injective?, Pacific J. Math. 45, 97-112. Faith, C. (1974a) On the structure of indecomposable injective modules, Comm. in Algebra, 2, 559-71. Faith, C. (1974b) On hereditary rings and Ann Boyle's conjecture. Faith, C. & Utumi, Y. (1965) On Noetherian prime rings, Trana. Amer. Math. Soc. 114, 1084--9. Faith, C. & Walker, E. (1967) Direct-sum representations of injective modules, J. Algebra, 5 (2), 203--21. Findlay, G. & La.mbek, J. (1958) A generalized ring of quotients I, II, Can. Math. Bull. 1, 77-85, 155--67. Gabriel, P. (1962) Des categories a.beliennes, Bull. Soc. Math. France, 90, 323--448. Goldie, A. W. (1958) The structure of prime rings under the ascending chain condition, Proc. Lond. Math. Soc. (3), 8, 589--608. Goldie, A. W. (1960) Semiprime rings with maximum condition, Proc. Lond. Math. Soc. (3), 10, 201-20. Goldie, A. W. (1962) Noncommuta.tive principal ideal rings, Archiv. Math. 13, 213-21. Goldie, A. W. (1969) Some aspects of ring theory, Bull. Lond. Math. Soc. 1, 129-54. Goodea.rl, K. R. (1972) Singular torsion and the splitting properties, Amer. Math. Soc. Memoirs, No. 124. Goodea.rl, K. R. (1975) Subrings of idealizer rings, J. Algebra, 33 (3), 405-29. Hart, R. (1967) Simple rings with uniform right ideals, J. Lond. Math. Soc. 42, 614--7. Hart, R. (1971) Krull dimension and global dimension of simple Ore-extensions, Math. Zeit. 121, 341-5. Hart, R. & Robson, J. C. (1970) Simple rings and rings Morita. equivalent to Ore domains, Proc. Lond. Math. Soc. (3) 21, 232-42. Hirsch, K. A. (1937) A note on noncommuta.tive polynomials, J. Lond. Math. Soc. 12, 264--6. Jacobson, N. L. (1943) The Theory of Rings, Amer. Math. Soc. Mathematical Surveys, Vol. 2, Providence, R.I.
References
131
Jacobson, N. (1945) The structure of simple rings without finiteness assumptions, Tram. Amer. Math. Soc. 57, 228-45. Jacobson, N. L. (1964a) Structure of Rings, rev. ed., Amer. Math. Soc. Colloq. Publ., vol. 37, Providence, R.I. Jacobson, N. L. (1964b) Lectures in Abstract Algebra, Vol. 3, The Theory of Fields, Van Nostrand, New York. Ja.ns, J. P. (1964) Rings and Homology, Holt, New York. Ja.tega.onka.r, A. V. (1969) Ore domains and free algebras, Bull. Lond. Math. Soc. 1, 45-6. Ja.tega.onka.r, A. V. (1971) Endomorphism rings of torsionleBB modules, Tram. Amer. Math. Soc. 161, 457-66. Johnson, J. L. (1971) Extensions of differential modules over formal power series rings, Amer. J. Math. 43 (3), 731-41. Johnson, R. E. (1951) The extended centralizer of a. ring over a. module, Proc. Amer. Math. Soc. 2, 891-5. Johnson, R. E. & Wong, E. T. (1959) Self-injective rings, Can. Math. Bull. 2, 167-73. Johnson, R. E. & Wong, E. T. (1961) Quasi-injective modules and irreducible rings, J. Lond. Math. Soc. 36, 260-8. Ka.pla.nsky, I. (1952) Modules over Dedeking rings and valuation rings, Tram. Amer. Math. Soc. 72, 327-40. Kothe, G. (1935) Verallgemeinerte Abelsche Gruppen mit Hypercomplexen opera.toren ring, Math. Zeit. 39, 31-44. La.mbek, J. (1966) Lectures on Rings and Modules, Ginn·Bla.isdell, Waltham, Mass. La.mbek, J. (1971) Torsion Theories, AdditiveSemantica, and Rings of Quotients, Lecture Notes in Mathematics, No. 177, Springer-Verlag, New York-Berlin. Lesieur, L. & Croisot, R. (1959) Surles a.nnea.ux premiers noetheriens a. gauche, Ann. Sci. Ecole Norm. Sup. 76, 161-83. Levy, L. (1963) Torsion free and divisible modules over nonintegra.l domains, Can. J. Math. 15, 132-57. Littlewood, D. E. (1933) On the classification of algebras, Proc. Lond. Math. Soc. (2), 35, 200-40. Malgrange, B. (1966) Cohomologie de Spencer (d'apres Quillen), Orsa.y. Ma.tlis, E. (1958) Injective modules over Noetherian rings, Pacific J. Math. 8, 511-28. Ma.tlis, E. (1968) Reflexive domains, J. Algebra, 8, 1-33. Michler, G. (1969) On quasi local Noetherian rings, Proc. A mer. Math. Soc. 20, 222-4. Michler, G. 0. & Villa.ma.yor, 0. E. (1973) On rings whose simple modules are injective, J. Algebra, 25, 185-201. Morita., K. (1958) Duality for modules and its applications to the theory of rings with minimum condition, Sci. Rep. Tokyo Kyoiku Daigaku Sect. A, 6, 83-142. Ore, 0. (1931) Linear equations in non-commutative fields, Ann. Math. 32, 463-77. Ore, 0. (1933) Theory of non-commutative polynomials, Ann. Math. 34, 480-508. Ornstein, A. Ph.D. Thesis, Rutgers University, 1967. Osofsky, B. L. (1968) Noninjective cyclic modules, Proc. Amer. Math. Soc. 19, 1383-4. Osofsky, B. L. (1971) On twisted polynomial rings, J. Algebra, 18, 597607.
132
References
Pa.pp, Z. (1959) On algebraically closed modules, Publ. Math. Debrecen. 6, 311-27. Popesco, N. & Gabriel, P. (1964) Ca.ra.cterisa.tions des categories a.beliennes avec genera.teurs et limites inductives exa.ctes, C.R. Acad. Sci. Paris, 258, 4188-90. Ra.mra.s, M. (1969) Maximal orders over regular local rings of dimension two, Trana. Amer. Math. Soc. 142, 457-79. Ra.mra.s, M. (1971) Maximal orders over regular local rings, Trana. A mer. Math. Soc. 155 (2), 345-52. Rinehart, G. S. (1962) Note on the global dimension of a. certain ring, Proc. Amer. Math. Soc. 13, 341-6. Robinson, A. (1963) Introduction to Model Theory and the Meta-Mathematics of Algebra, North Holland, Amsterdam. Robson, J. C. (1972) Idealizers and hereditary Noetherian prime rings, J. Algebra, 22, 45-81. Roos, J. E. (1972) Algebre homologique. Determination de la. dimension homologique globa.le des a.lgebres de Weyl, C. R. Acad. Sci. Paris Ser. A, 274, 23-6. Sa.ndomierski, F. L. (1968) Nonsingula.r rings, Proc. Amer. Math. Soc. 19, 225-230. Silver, L. (1967) Noncommuta.tive localizations and applications, J. Algebra, 7, 44-76. Steinitz, E. (1948) Algebraiache Theorie der Korper, Chelsea., New York. Swan, R. G. (1962) Projective modules over group rings and maximal orders, Ann. Math. 76, 55-61. Utumi, Y. (1956) On quotient rings, Osaka Math. J. 8, 1-18. Utumi, Y. (1963) A Theorem of Levitzki, Math. Assoc. of Amer. Monthly, 70, 286. Webber, D. B. (1970) Ideals and modules of simple Noetherian hereditary rings, J. Algebra, 16, 239-42. Wedderburn, J. H. M. (1908) On hypercomplex numbers, Proc. Lond. Math. Soc. (2), 6, 77-117. Zelma.nowitz, J. M. (1967) Endomorphism rings of torsionleBB modules, J. Algebra, 5, 325-41.
Index
AI, 46, 125 a..c.c., 2 a..c.c.~, 27 a..c.c. EB, 22 adjoint (left), 123 algebra. of quantum mechanics, 125 Amitsur-Littlewood domains, 6, 43, 50 annihilator, 24 a.nnulet, 24 Artinia.n module, xiv Artinia.n ring, xiv ascending chain condition, 2 Auslander global dimension theorem, 121 Ba.er's criterion, 83 balanced module, xiv basis of a. module, xiv Bass' global dimension two theorem, 78 biendomorphism ring, xiv Boyle's conjecture, 116 Boyle's theorem, 112 Ca.rta.n-Bra.uer-Hua. theorem, 118 category, 122 cogenera.tor, 85 complement right ideal, 38 completely injective module, 102 constants of a. derivation, 44 contravariant functor, 123 correspondence theorem for projective modules, 17 covariant functor, 123 cut-down proposition, 10 d.c.c., 32 degree of a. differential polynomial, 43 ll·inva.ria.nt ideal, 44 derivation, 42 descending chain condition, 32 differential module, 49 differential polynomial ring, 43, 50
direct sum, xiv direct summand, xiv division algebra., 118 domain, xvii dual basis lemma., 9 dual (categories), 37 duality, 37 endomorphism ring, xiii endomorphism ring and projective module theorem, 28 endomorphism ring theorem, 1, 28 epi, xiv epimorphism, xiii equivalence (functor), 123 equivalence (map), 123 equivalent categories, 123 equivalent orders, 26 essential extension, 20 exact sequence, xv Ext'(-, - ), 121 Fa.ith-Utumi theorem, 5, 67 field, xvii filter, 114 finite dimensional module, 22 fir, 111 flat module, 122 free basis of a. module, xiv Frobenius map, 95 full (right) linear ring, 88 functor, 123 G·inva.ria.nt subset, 51 generator, 8 global dimension, 121 global dimension two theorem, 4, 41 Goldie dimension, 22 Goldie ring, 27 Goldie-Lesieur-Croisot theorem, 65 Hart's theorem, 28 hereditary ring, 33 hereditary ring theorem, 3, 33 Hilbert basis theorem, xvi
[ 133]
Index
134 homological dimension of a. module, 121 Hopkins-Levitzki theorem, 125 idealizer, '24 idempotent right ideal theorem, 2, 30 inner derivation, 42 injective hull, 84 injection, xiv injective mapping, xiv injective module, 83 Jacobson domains, 6, 61 Johnson-Utumi maximal quotient ring, 21 J orda.n-Weyl-Littlewood algebra., 125 Krull dimensional
~
1, 116
lateral right ideal, 23 l.d.o., 43 least ideal theorem, 2, 25 left equivalent ( ~) orders, 26 map, 122 matrix units, 67 maximal equivalent ( :t) order, 27 maximal left equivalent (~)order, 27 maximal order theorem, 3, 76 maximal rational extension, 21 maximal right equivalent ( ~) order, 27 maximal submodule, xvi maximum condition, xv minimum condition, xvi mono, xiv monomorphism, xiv Morita. equivalent, 15 Morita. invariant (property), 15 morphism, 122 natural isomorphism, xv naturally equivalent functors, 123 neat ring, 99 nil right ideal, 64 Noetherian module, xv N oetheria.n ring, xvi order, 72 Ore condition, 65 Ore domain, 27 Osofsky's theorem, 99 partial differential ring, 50 PCI.ring, 98
pli·(pri·) domain, 6 Popesco-Ga.briel theorem, 124 prime ring, xvii primitive ring, 62 principal right ideal theorem, 5, 70 progenera.tor, 14 projective dimension of a. module, 121 projective module, 9 projective module theorem, 2, 28 projective resolution of a. module, 121 proper cyclic, 98 q.field, 97 QI-ring, 116 quasi-injective module, 85 quoring, 26 quotient ring, 26 ra.d (radical), xiv rational extension, 20 reflexive ideal theorem, 4, 79 reflexive module, 50 regular ring, 83, 122 relative complement, 38 restricted (right) minimum condition, 116 p-deriva.tion, 52 right equivalent ( ~) orders, 26 right order, 26 ring of linear differential operators, 43, 50 ring·l, xiii Ritt algebra., 43 RRM,ll6 same centers theorem, 3, 26 Scha.nuel's lemma., 11 semiheredita.ry ring, 101 semiprime ring, xvii semisimple module, xvi sequence, xv short exact sequence, xv a-cyclic module, 106 L-cyclic module, 109 similar rings, 15 simple endomorphism rings theorem, 4, 29 simple localization, 6, 52 simple module, xvi simple ring, xvii single ideal theorem, 2, 26 singular ideal, 65 singular submodule, 20 skew polynomial ring, 52
Index soc (socle), xvi Steinitz extension, 118 subdirect product, 90 surjection, xiv surjective mapping, xiv summand, xiv torsion element of a. module, 36 torsion free module, 36 torsion module, 36 torsion submodule, 36 torsionless module, 50 trace, 8 twisted, finite Laurent polynomials,
95
135 twisted group ring, 50 ultrafilter, 114 ultra.product, 115 uniform module, 28 uniqueness of orders theorem, 2, 31 universal differential field, 7, 94 Utumi's theorem, 122 V-ring, 86 Von N euma.nn regular ring, 83, 122 Webber's theorem, 35 Wedderburn-Artin theorem, 32