A-Solvable Groups and the Torsion-Freeness of Ext

International Journal of Algebra, Vol. 13, 2019, no. 3, 137 - 141 HIKARI Ltd, www.m-hikari.com https://doi.org/10.12988/ija.2019.9210

A-solvable Groups and the Torsion-Freeness of Ext

Ulrich Albrecht

Department of Mathematics Auburn University, Auburn, AL 36849, USA

Stefan Friedenberg

University of Stralsund Zur Schwedenschanze 15, 18435 Stralsund, Germany

This article is distributed under the Creative Commons by-nc-nd Attribution License. Copyright c 2019 Hikari Ltd.

Abstract Since the group Ext(A, B) is divisible for any torsion-free group A, the natural question arises, when Ext(A, B) is torsion-free - espe- cially without vanishing. While the class ∗B of all groups A such that Ext(A, B) is torsion-free was discussed in several publications, for example see [4] and [5], there is less known about the dual class A∗. This paper investigates some homological properties of the class of Abelian groups B such that Ext(A, B) is torsion-free. Moreover, we compare the 1 ranks of the divisible groups Ext(A, B) and BextB(A, B) whenever A is a countable torsion-free B-solvable group and B has a right hereditary endomorphism ring.

Mathematics Subject Classiﬁcation: 20K15, 20K35

Keywords: Abelian group, extension, torsion-free, solvable group

1 Introduction

Every Abelian group B induces functors HB(·) = Hom(B, ·) and TB(·) = ·⊗E B between the category of Abelian groups and the category of right E-modules where E = E(B) denotes the endomorphism ring of B. These functors induce natural maps θA : TBHB(A) → A and φM : M → HBTB(M) deﬁned by θA(α ⊗ a) = α(a) and [φM (x)](a) = x ⊗ a for all α ∈ HB(A), x ∈ M, and a ∈ B. A group A is B-generated if SB(A) = A where SB(A) = im(θA), and 138 Ulrich Albrecht and Stefan Friedenberg

it is B-solvable if θA is an isomorphism. Moreover, a group P is (finitely) B- projective if it is a direct summand of ⊕I B for some (finite) index-set I. If B is a torsion-free group of finite rank, then all B-projective groups are B-solvable.

2 First results on the class A∗

Throughout this paper all groups are assumed to be torsion-free Abelian groups of finite rank. By Warfield this implies that the p-rank of Ext(A, B) can be calculated by rp(Ext(A, B)) = rp(A) · rp(B) − rp(Hom(A, B)), where rp(A) means dimZ/pZ(A/pA) if A is torsion-free. Furthermore, Arnold showed that ∗ 2 A ∈ A if and only if A is a finietly faithful S-group, i.e. rp(End(A)) = (rp(A)) Q ∼ Q ∗ for all primes p. Since Ext(A, Bj) = Ext(A, Bj) the class A is trivially j∈J j∈J closed under direct products. Moreover we conclude

Theorem 2.1 The class A∗ is closed under epimorphic images. Proof: Considering the short exact sequence 0 → B0 → B → B/B0 → 0 we obtain the exact sequence · · · → Ext(A, B0) →α Ext(A, B) → Ext(A, B/B0) → 0. Since A is torsion-free Ext(A, B0) is divisible and so is Im(α). Thus the short exact sequence

0 → Im(α) → Ext(A, B) → Ext(A, B/B0) → 0 splits and hence Ext(A, B) ∼= Ext(A, B/B0)⊕Im(α) which implies that Ext(A, B/B0) is torsion-free whenever Ext(A, B) is. 2

Note that this theorem fails if A is not torsion-free. For example, choose 0 A = Zp∞ , B = Z and B = pZ. Then Ext(Zp∞ , Z) is torsion-free, because it is isomorphic to the p-adic completion of Jp, the additive group of the p-adic integers, but Ext(Zp∞ , Z/pZ) is torsion. This argument underlines our general restriction on torsion-free groups.

Goeters has shown in [11], that a group A, fulﬁlling Ext(A, B) is torsion- free and OT (B) 6= tp(Q), is projective with respect to any pure exact sequence 0 0 0 0 → B →∗ B → B/B → 0, which means that any element of Hom(A, B/B ) extends to an element of Hom(A, B). In this case we receive a short exact sequence 0 → Ext(A, B0) →α Ext(A, B) → Ext(A, B/B0) → 0. Hence also Ext(A, B0) is torsion-free. Unfortunately this is not true, if OT (B) = tp(Q). For example let A = B be the Corner-group of rank 2. Then B is torsion-free, any pure subgroup B0 < B of rank 1 is free and the qoutient-group B/B0 is divisible. Fur- thermore, we have End(B) = Z. By applying Hom(−, Z) to the short exact sequence 0 → Z → B → Q → 0 we obtain the exact sequence Hom(Z, Z) = α Z → Ext(Q, Z) → Ext(B, Z) → 0 = Ext(Z, Z). Since Q is divisible the A-solvable groups and the torsion-freeness of Ext 139

L group Ext(Q, Z) is torsion-free and hence of the form Ext(Q, Z) = Q. So 2ℵ0 Ker(α) cannot be a pure subgroup of Ext(Q, Z) and hence Ext(B, Z) cannot be torsion-free. On the other hand, Ext(B,B) is torsion-free since B is a Murley group and hence a ﬁnitely faithful S-group.

This gives raise to our more restrictive approach of considering:

3 Some properties of A∗ for B-solvable groups

As turned out, some properties of an Abelian group B are often better described by considering subgroups of Ext, as can be seen in the discussion of Butler groups. Similarly, the group Ext(A, B) is not always the right tool to study homological properties of B-solvable groups. These are better described 1 by the subgroup BextB(A, H) of Ext(A, H). It consists of the equivalence classes of sequences 0 → H → X → A → 0 with A and HB-solvable with respect to which B is projective [3].

Theorem 3.1 The following conditions are equivalent for a torsion-free Abelian group B of ﬁnite rank.

2 a) rp(E) = [rp(B)] for all primes p. b) If A is a torsion-free B-solvable group and H is B-generated, then there 1 is a monomorphsim α : ExtE(HB(A),HB(H)) → Ext(A, H) such that coker α is torsion-free divisible.

Proof: a) ⇒ b): Since B is a ﬁnitely faithful S-group, Ext(B,B) is torsion-free. For an B-generated torsion-free group H, consider a quasi-splitting exact sequence 0 → H → X → B → 0. Observe that X is a torsion-free group . such that SB(X) = X. Since B is a ﬁnitely faithful S-group, SB(X) is also pure in X. Thus, X = SB(X) and the last sequence splits because B has a hereditary endomorphism ring. Therefore, Ext(B,H) is torsion-free. For a torsion-free B-solvable group A, there is an exact sequence 0 → U → F → A → 0 such that U is B-generated and F is a direct sum of copies of B with respect to which B is projective. It induces the exact sequence

0 → HB(U) → HB(F ) → HB(A) → 0 of right E-modules which in turn induces the top-row of the commutative diagram

1 HomE (HB (F ),HB (H)) → HomE (HB (U),HB (H)) → Ext (HB (A),HB (H)) → 0   E  ∼  ∼   = y = y y θF θU α Hom(F,H) → Hom(U, H) → Ext(A, H) → Ext(F,H) 140 Ulrich Albrecht and Stefan Friedenberg

in which the ﬁrst two vertical isomorphisms are given by the adjoint func- tor theorem and the fact that U and F are B-solvable, too. A diagram chase shows that the induced map α is a monomorphism. By the result of the ∼ ﬁrst paragraph, Ext(⊕I B,H) = ΠI Ext(B,H) is torsion-free, and coker α is torsion-free divisible. 1 b) ⇒ a): By b) there exists an exact sequence 0 = ExtE(E,E) → Ext(B,B) → D → 0 in which D is torsion-free divisible. 2

Corollary 3.2 The following are equivalent for a torsion-free Abelian group B of ﬁnite rank: a) B is a ﬁnitely faithful S-group. b) Ext(A, H) is torsion-free whenever H is a torsion-free B-generated group and A is a pure subgroup of Bn for some n < ω. Proof: It remains to show a) ⇒ b): By Theorem 3.1, we know that 1 there is an exact sequence 0 = ExtE(E,HB(H)) → Ext(B,H) → D → 0 in which D is torsion-free divisible. Thus Ext(Bn,H) is torsion-free for all n < ω. Because A is a pure subgroup of Bn, we obtain an exact sequence Ext(Bn/A, H) → Ext(Bn,H) → Ext(A, H) → 0 in which Ext(Bn/A, H) is divisible. Thus, Ext(A, H) is isomorphic to a direct summand of the torsion-free group Ext(Bn,H). 2

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Received: March 11, 2019; Published: April 8, 2019