LIMITS OF SEQUENCES OF FINITELY GENERATED ABELIAN GROUPS

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LIMITS OF SEQUENCES OF FINITELY GENERATED ABELIAN GROUPS PAUL HILL1 1. Introduction. The limits referred to in the title are the ordinary direct and inverse limits, but for our purpose we shall require throughout 2 and 3 that the homomorphisms associated with direct limits be monomorphisms and that those associated with inverse limits be epimorphisms. Denote by Qd (Qr) the collection of sequences of groups for which a direct (inverse) limit exists and is determined up to isomorphism solely by the groups, that is, is independent of the choice of the monomorphisms (epimorphisms). In 2 and 3, respectively, the sequences of finitely generated abelian groups belonging to Qd and 6/ are determined. A characterization of inverse limits of sequences of finitely generated abelian groups is given in 4. Since our attention will be restricted to abelian groups, "abelian group" is abbreviated to "group". With one exception, all groups are considered discrete. 2. Direct limits. We wish to consider only sequences G which admit monomorphisms from Gn to Gn+i; such sequences will be called ascending. A basis [gi, g2,, gk] of a finite primary group is said to be written in canonical form if its elements are arranged in decreasing order, 0(gi+i) = 0(g() for l=i<k where 0(x) denotes the order of x. Let Gn be an ascending sequence of finite ^-primary groups with canonical bases [gi,n, gi.n,, g*(»),n]- Notice that the sequences k(n) and 0(giin) (with i fixed) are monotonie since Gn is ascending. The rank (finite or o) of the sequence G is defined as r = limn^x k(n), and for each natural integer i^r, m is defined by pm< = lim ^a> 0(gi,n). Set m = min {nii}. The sequence Gn is called irregular if for some fixed mo<m the relation 0 (gi,n) =pm holds for almost all n with a suitable choice of i, that is, Gn is irregular if all but a finite number of the groups Gn contain a summand of the same order pmo<pm. Sequences are said to be regular if they are not irregular. Obviously, if the rank of the sequence G is finite, then Gn is regular. Theorem 1. A necessary and sufficient condition for an ascending sequence Gn of finite primary groups to belong to QD is that Gn be regular. Proof. The fact that the condition is necessary is almost trivial. Received by the editors November 2, 1960. 1 A National Science Foundation postdoctoral fellow. 946

finitely generated abelian groups 947 The most natural2 direct limit of Gn is A = 2~l C(Pmi), where C(pmi) is the cyclic group of order pmi for finite w and C(p ) is quasicyclic ( = group of type pm). However, if Gn is irregular, almost all the groups Gn contain a cyclic summand (isomorphic to) C(p ) where m0<m; clearly, this summand can be preserved (as a summand) in some direct limit. Since such a limit cannot be isomorphic to A, GnC^D. In order to prove that regularity is sufficient, let Gn be regular and let B be an arbitrary direct limit of Gn. Use is made of the limit A defined above; we show that B=A. Recall that a direct limit L of Gn (under monomorphisms) is the set-theoretical union of groups isomorphic to the G ; A = UT7 where Hn=Gn and Hn^Hn+i. Thus it is immediate (whether G is regular or not) that the rank (for definition, see [l]) of 73 is precisely the rank of the sequence Gn, r(b) =r. If m= <x>, then B is divisible; for otherwise B would have a cyclic summand C (j^o), which would imply that almost all the G contained a summand isomorphic to C. Since Gn is regular, this is impossible. Thus T3=^4 since both are divisible with the same rank, and the theorem is proved in the case m = o. For the case m<<*>, let B=Br Bd where BR is reduced and Bo is divisible. BR is bounded since Br unbounded implies that BR = Ci C2 Ck B, where k and the orders of the cyclic groups d are arbitrarily large; but this implies m=», Hence Br is a direct sum of cyclic groups, and 73=T3i T32 BD where T3 is a direct sum of cyclic groups of order pi. Since G is regular, Bi = B2= =73m_i = 0. Using the corresponding notation, we write A =Am Am+i AD. It is immediate that plb (t = Q) is a direct limit of the sequence p'gn; hence the rank of p'b is determined solely by the groups G. Thus Ad=Bd since the reduced parts of A and B are bounded. Moreover, r(pmb)=r(pma) < o, and r(am) = r(a) hence ^4m=T3OT. Similarly, - r(p A) = r(b) - r(pmb) = r(bm); r(am+1) = r(pmb) - r(pm+'b) = r(bm+i); Am+i-= Bm+i, etc. Since any subgroup ^0 of the additive rationals is a direct limit of infinite cyclic groups, we have at once Corollary 1. An ascending sequence Gn of finitely generated groups belongs to Qd if and only if the groups Gn are finite and the p-primary components form a regular sequence for each prime p. The limit A is obtained merely by identifying g,, with a multiple of g,n+i.

948 PAUL HILL [December 3. Inverse limits. Here, we wish to consider only sequences G which admit epimorphisms from Gn+i to Gn; such sequences will be called extending. However, a sequence of finite (abelian) groups is extending if and only if it is ascending; hence the terminology established in 2 carries over to extending sequences of finite»-groups. Theorem 2. A necessary and sufficient condition for an extending sequence Gn of finite primary groups to belong to Cj is that Gn be regular. Proof. Again, it is immediate that the condition is necessary. In fact, one needs only to make the obvious replacements in the proof of Theorem 1. Recall that Z > the direct sum, should be replaced by Z' i the complete direct sum, and the group of type px by the -adic group. Denote by G* the (discrete) character group of G. With an inverse sequence (1) Gi<-Gt<-*- Gn <- there is associated in a natural way a (unique) direct sequence (2) Gf -» G2* ->-> G* -», which in turn gives rise to an inverse sequence (3) Gf* <- G2** <-<- G** <-. Together with the usual isomorphism (see, for example, [2]) between G and G**, (1) and (3) form a commutative diagram and therefore have isomorphic limits. However, the limit of (3) is the character group of the limit of (2). Thus if G is regular, by Theorem 1 the limit of (1) is determined by the groups alone and GnCQi- Now let Gn be an extending sequence of finitely generated groups. Analogous to the -rank of a sequence, the torsion free rank of the sequence G is defined as the limit of the torsion free ranks of the groups Gn, ro = limb<00 r0(gn). The question of whether or not G is contained in Qi depends to a large degree on whether ra is finite or not; consequently, the two cases are distinguished. Corollary 2. Let Gn be an extending sequence with finite torsion free rank of finitely generated groups. A necessary and sufficient condition for Gn to belong to 6/ tí that the p-primary components form a regular sequence for each prime p. Proof. Denoting the torsion free rank of the sequence G by ra, we may as well assume that the torsion free rank of the group G is r0 for each n. Clearly, an inverse limit of G is the free group of rank

i96i] FINITELY GENERATED ABELIAN GROUPS 949 r0 plus a limit of the torsion subgroups by Theorem 2. of GH. The proof is completed Corollary 3. Let G be an extending sequence with infinite torsion free rank of finitely generated groups. A necessary and sufficient condition for Gn to belong to 6/ is that the torsion subgroups of Gn do not contribute to any inverse limit of G, that is, there is no nonzero limit element {Xn} where x is torsion for all n. Proof. It is clear that the complete direct sum of a countably infinite number of infinite cyclic groups is an inverse limit of G ; denote this group by A. Let 73 be an arbitrary inverse limit of G and let C denote the subgroup of B which comes from the torsion subgroups, Tn, of Gn. Then T3/C, isomorphic to an inverse limit of G /Tn (since the Tn are finite), is isomorphic to A. Hence if C=0, then B=A; but if Cs^O, then it contains either a cyclic group of prime order or a -adic group, so B is not isomorphic to A. 4. Totality of limits. The requirement that the homomorphisms associated with direct and inverse limits be monomorphisms and epimorphisms, respectively, is dropped. It is immediate that the direct limits of sequences of finitely generated groups are just the countable groups. The class of inverse limits of such sequences is given by the following Theorem 3. A necessary and sufficient condition for a group G to be an inverse limit of a sequence of finitely generated (abelian) groups is that G be the complete direct sum of (at most) a countable number of cyclic and p-adic groups. Proof. It is obvious that the condition is sufficient. In order to prove that it is necessary, let G be an inverse limit of a sequence Gn of finitely generated groups and let C denote the subgroup of G which comes from the torsion subgroups, Tn, of G. The factor group G/C, isomorphic to an inverse limit of Gn/Tn, is the complete direct sum of a countable number of infinite cyclic groups. It is well known that C admits a compact topology in which it is totally disconnected and satisfies the second axiom of countability. Since the Pontrjagin dual group C* of C is countable, it follows from the proof of Proposition 3.1 of [3] that C is a complete direct sum of a countable number of cyclic and -adic groups. Since C is compact, it is algebraically compact [4]; hence its purity implies that it is a direct summand of G, and the theorem is proved. 5. Remark and example. In conclusion we add the following remark relevant to 2 and 3. There are direct (inverse) sequences,

950 PAUL HILL even of finite groups, which have two nonisomorphic limits associated with monomorphisms (epimorphisms) p and <pn, respectively, such that pny^(pn only if both p and <pn are onto isomorphisms. In fact, let G be a countable, reduced ^-primary group with (nonzero) elements of infinite height; an increasing sequence of finite subgroups G which leads up to G exhibits such a sequence if the G are chosen such that the index of G in Gre+i is 0 or p, depending on whether n is odd or even. References 1. L. Fuchs, Abelian groups, Budapest, Publishing House of the Hungarian Academy of Sciences, 1958. 2. M. Hall, The theory of groups, New York, The Macmillan Company, 1959. 3. D. K. Harrison, Infinite abelian groups and homological methods, Ann. of Math. vol. 69 (1959) pp. 366-391. 4. J. Los, Abelian groups that are direct summands of every abelian group which contains them as pure subgroups, Fund. Math. vol. 44 (1957) pp. 84-90. Institute for Advanced Study

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