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On Generalized Dedekind Groups and Tarski Super Monsters1 Journal of Algebra 226, 690᎐713Ž. 2000 doi:10.1006rjabr.1999.8106, available online at http:rrwww.idealibrary.com on On Generalized Dedekind Groups and Tarski Super Monsters1 Marcel Herzog View metadata, citation and similar papers at core.ac.uk brought to you by CORE School of Mathematical Sciences, Raymond and Be¨erly Sackler Faculty of Exact Sciences, Tel-A¨i¨ Uni¨ersity, Tel-A¨i¨, Israel provided by Elsevier - Publisher Connector Patrizia Longobardi Dipartimento di Matematica e Appl.ni, Uni¨ersitaÁ degli Studi di Napoli, Monte S. Angelo, ¨ia Cinthia, 80126 Naples, Italy Mercede Maj Dipartimento di Matematica e Informatica, Uni¨ersitaÁ di Salerno, ¨ia Sal¨ator Allende, 84081 Baronissi() Salerno , Italy and Avinoam Mann Institute of Mathematics, Hebrew Uni¨ersity, Jerusalem, Israel Communicated by Walter Feit Received October 6, 1998 I. INTRODUCTION Let G be a group and suppose that GЈ is of prime order. If x g G and U g y Ј s wxF ²x :G then for each g G NxG Ž² :.we have G ² x, g : g g ² x, x :², whence x, x :Žeᎏ G. We shall call a group G a J-group G g J for g short.² if each x g G satisfies either x:eᎏᎏG or ²x, x :eG for all g g G y NxGŽ² :.. This paper is devoted to the investigation of non-abelian 1 M. H. and A. M. are grateful to the Department of Mathematics of the University of Napoli for its hospitality while this investigation was carried out. Their visits were supported by C.N.R. grants. 690 0021-8693r00 $35.00 Copyright ᮊ 2000 by Academic Press All rights of reproduction in any form reserved. DEDEKIND GROUPS AND TARSKI MONSTERS 691 J-groups. These groups may be considered as a generalization of Hamilto- nian groups. As we have just seen, they include groups with a commutator subgroup of prime order. But this condition is not necessary. For example, the Tarski Monsters, which are infinite simple groups with all proper subgroups of a fixed prime order, are J-groups and, in the finite domain, SLŽ.2, 3 is a J-group with the commutator subgroup quaternion of order 8. We shall see that J-groups are either close to commutativity, in some sense, or they involveŽ. generalized Tarski Monsters. It is clear that the J-property is inherited by subgroups and quotient groups. Some examples of finite non-abelian J-groups are the p-groups of order p3 for any prime p, the quaternion group of order 16, the Frobenius groups of order pq with p, q being primes, and the above mentioned SLŽ.2, 3 . It is surprising that for the finitely generated infinite non-abelian solvable groups and for the finitely generated infinite non-abelian locally graded groups, we have: G g J if and only if GЈ is of prime order Ž.Theorem 24 and Corollary 26 . On the other hand, an infinite simple group G is a J-group if and only if all its proper subgroups are abelian Ž.Theorem 32 . A similar result holds for infinite perfect groupsŽ Theorem 34. In Section II we investigate finite J-groups. We prove in Theorem 1 that such groups are always solvable and in Theorem 6 we characterize the non-nilpotent finite J-groups G modulo their hypercenter, which by Proposition 11 equals ZG3Ž.. The main problem in the finite case remains the structure of finite p-groups belonging to J. These groups are investi- gated in Section III. It is shown that if G g J is a non-abelian finite p-group, then clŽ. G F 3 and dl Ž. G s 2 Ž Proposition 10 . This result is the best possible, as witnessed by the quaternion group of order 16. If p ) 2, then expŽ.GЈ s p and <<GЈ F p2, and if p s 2 then expŽ.GЈ F 4 and X <G < F 26 Ž.Ž Theorem 13 and Corollary 22 . If p ) 3, then cl G.s 2Ž Theo- rem 14.Ž . Moreover, if p s 3 and cl G.s 3, then G is almost completely determinedŽ. Theorem 23 . Since by Proposition 10 finite nilpotent J-groups satisfy dlŽ. G F 2, it can be shown, using Theorem 6, that if G is an arbitrary finite J-group then dlŽ. G F 3 Ž Proposition 11. This result is the best possible, as witnessed by SLŽ.2, 3 . Section IV is devoted to solvable infinite J-groups. First we prove that if G is a finitely generated infinite non-abelian group, then G is a solvable J-group if and only if GЈ is of prime orderŽ. Theorem 24 . It follows, using Proposition 11, that if G is an arbitrary non-abelian locally solvable J-group, then G is solvable, dlŽ. G F 3, and either GЈ is of prime order or G is locally finiteŽ. Corollary 25 . These results are also true if we replace the word ``solvable'' by ``locally graded''Ž. Corollary 27 . Moreover, it follows from Theorem 24 that if G is a finitely generated infinite non- 692 HERZOG ET AL. abelian group, then G is a nilpotent J-group if and only if GЈ is a subgroup of ZGŽ.of prime order Ž Corollary 28 . This implies that if G is an arbitrary non-abelian locally nilpotent J-group, then G is nilpotent, clŽ. G F 3, and either GЈ is a subgroup of ZG Ž.of prime order or G is locally finiteŽ. Corollary 29 . Finally, if G is an infinite locally finite J-group, then G is solvable and either G is nilpotent of class at most 3, or r G ZG3Ž.is a finite Frobenius group of the special type described in Theorem 5Ž. Theorem 30 . In Section V we describe non-solvable infinite J-groups. It is here that the Tarski Super Monsters appear. An infinite simple group is called a Tarski Super Monster Ž.TSM for short if all its proper subgroups are abelian. First we show that an infinite simple group G is a J-group if and only if it is a TSMŽ. Theorem 32 . It turns out that every infinite non-solva- ble J-group G has a normal series 1 F K F N F G with GrN a Dedekind group, K s ZNŽ.s ⌽ Ž.N , and NrK a TSMŽ. Theorem 33 . Moreover, we show that a perfect infinite group is a J-group if and only if it is a Perfect Tarski Super MonsterŽ. Theorem 34 , where a Perfect Tarski Super Monster is a perfect infinite group with all proper subgroups abelian. It is worth mentioning that Tarski Super Monsters which are not Tarski Monsters exist. It was proved by Obraztsovwx 5 , using Ol'shanskiõ'sÏ methods, that if A is a nontrivial finite or countably infinite group without an involution and n is a sufficiently large fixed odd number Žn ) 2 и 1077 will do. , then there exists a countable 2-generator simple group G containing A, such that every proper subgroup of G is either cyclic of order dividing n or is conjugate to a subgroup of A. So if we take for A an arbitrary non-cyclic finite or countably infinite abelian group, then G will be a Tarski Super Monster, but not a Tarski Monster. We conclude this introduction with a description of our notation. A group is called a Dedekind group if all its subgroups are normal. A non-abelian Dedekind group is called a Hamiltonian group. A group G is called locally graded if each finitely generated subgroup of G has a non-trivial finite homomorphic image. If G is a group, then ZGŽ., ZGi Ž., and ZGϱŽ.denote the center, the ith center, and the hypercenter of G, respectively. The derived length of a solvable group G will be denoted by dlŽ. G and the class of a nilpotent group G will be denoted by cl Ž. G . The Frattini subgroup of G is denoted by ⌽Ž.G , G p s ² ggp < g G:, and s F < g F NormŽ.G Ä NaaGGŽ² :. G4.If A G then A denotes the core of A in G and AG denotes the normal closure of A in G. The set of elements of finite order in an infinite group G will be denoted by TGŽ..If x, y g G then wxx, y s xyxyy1 y1 .IfG is a finite group, then ␲ Ž.G denotes the set of primes which divide the order of G.IfG is a finite p-group, then bGŽ. bŽG. s w x< g ⍀ s g < p s is defined by p MaxÄ G: CaaGŽ. G4 and 1Ž.G ²g Gg n 1: . The generalized quaternion group of order 2 will be denoted by Q2 n. DEDEKIND GROUPS AND TARSKI MONSTERS 693 The authors are grateful to Professors A. Yu. Ol'shanskiõÏ and John Wilson for their helpful remarks and suggestions. II. PROPERTIES OF FINITE J-GROUPS In this section G denotes a finite group. First we show that finite J-groups are solvable. THEOREM 1. If G g J then G is sol¨able. Proof. By induction on <<G . If all maximal subgroups of G are nilpo- tent, then either G is nilpotent or by the Schmidt theorem G is solvable. So we may assume that G possesses a non-nilpotent maximal subgroup M. g U g y There exists x M such that ²x :M. Let g M NxM Ž² :.; then g H s ² x, x :eᎏ G.As1- H F M - G, by induction H and GrH are solvable and hence G is solvable.
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