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Article

On Groups in Which Many Automorphisms Are Cyclic

1
Dipartimento di Matematica e Applicazioni, Università di Napoli Federico II, 80138 Napoli, Italy
2
Dipartimento di Matematica e Fisica, Università della Campania “Luigi Vanvitelli”, 81100 Caserta, Italy
*
Author to whom correspondence should be addressed.
Mathematics 2022, 10(2), 262; https://doi.org/10.3390/math10020262
Submission received: 19 December 2021 / Revised: 8 January 2022 / Accepted: 13 January 2022 / Published: 15 January 2022
(This article belongs to the Special Issue Group Theory and Related Topics)

Abstract

:
Let G be a group. An automorphism α of G is said to be a cyclic automorphism if the subgroup x , x α is cyclic for every element x of G. In [F. de Giovanni, M.L. Newell, A. Russo: On a class of normal endomorphisms of groups, J. Algebra and its Applications 13, (2014), 6pp] the authors proved that every cyclic automorphism is central, namely, that every cyclic automorphism acts trivially on the factor group G / Z ( G ) . In this paper, the class F W of groups in which every element induces by conjugation a cyclic automorphism on a (normal) subgroup of finite index will be investigated.
MSC:
20E36; 20F24

1. Introduction

Let G be a group. Following the work in [1], an automorphism α of G is called a cyclic automorphism if the subgroup x , x α is cyclic for every element x of G. Clearly, any power automorphism of G (i.e., an automorphism which maps every subgroup onto itself) is cyclic; however, the multiplication by a rational number greater than 1 is a cyclic automorphism of the additive group of rational numbers which is not a power automorphism. Finally, it is easy to show that any cyclic automorphism of a periodic group is a power automorphism.
In [1], it was proved that any cyclic automorphism of a group G is central, i.e., it acts trivially on the factor group G / Z ( G ) . Notice that this result is an extension to cyclic automorphisms of a renowned theorem by Cooper [2] for power automorphisms. It is not difficult to prove that the set C A u t ( G ) of all cyclic automorphisms of G forms a normal abelian subgroup of the automorphism group A u t ( G ) of G. In [3], the structure of C A u t ( G ) has been investigated in detail and some well-known properties of power automorphisms (see in [2]) has been extended to cyclic automorphisms. Moreover, the groups in which every automorphism is cyclic have been characterized there.
In the following, we will say that an element g of a group G induces by conjugation a weakly cyclic automorphism of G if there exists a normal subgroup W ( g ) of G such that the index | G : W ( g ) | is finite and the subgroup x , x g is cyclic for each element x of W ( g ) . Let g 1 and g 2 be elements of G inducing weakly cyclic automorphisms and put W = W ( g 1 ) W ( g 2 ) . If x is an element of W, then x , x g 1 = y for some y W , and so x , x g 1 is contained in the cyclic subgroup y , y g 2 . It follows that g 1 g 2 induces a weakly cyclic automorphism of G and hence the set F W ( G ) of all elements of G inducing by conjugation weakly cyclic automorphisms of G is a subgroup of G. Moreover, if g is an element of F W , x is an element of W ( g ) and y is an element of G, we have that x y 1 , x y 1 g y is again a cyclic subgroup of W ( g ) , so that F W ( G ) is a normal subgroup of G. We name this subgroup the F W - c e n t r e of G. A group which coincides with its F W -center will be called an F W - g r o u p .
Recall that the cyclic norm  C ( G ) of a group G is defined as the intersection of the normalizers of every maximal locally cyclic subgroup of G. By [3], Lemma 2.1, any cyclic automorphism of G fixes all maximal locally cyclic subgroups of G. It follows that C ( G ) coincides with the set of all elements of G inducing cyclic automorphisms of G. In particular, C ( G ) is a subgroup of F W ( G ) .
In the first part of the article, the class FW of groups in which every element induces by conjugation a weakly cyclic automorphism will be investigated. In particular, it will be proved that the class FW coincides with the class FP recently studied by De Falco et al. [4]. Recall here that a group G is said to be an F P - g r o u p if every element of G induces by conjugation a power automorphism on some subgroup of finite index of G. Clearly, the groups with finitely many conjugacy classes (the so-called F C - g r o u p s ) are F P -groups, while every F P -group is an F W -group. The consideration of the infinite dihedral group D shows that there are F P -groups which are not F C -groups.
Let G be a group and denote by C y c ( G ) the set of all elements x of G such that x , y is cyclic for every y in G. It is easy to show that C y c ( G ) is a central, characteristic subgroup of G called the cyclicizer of G (see [5,6]). Clearly, C y c ( G ) is locally cyclic and hence every automorphism of G induces a cyclic automorphism on C y c ( G ) . In the last part of the article, groups with non-trivial cyclicizer will be investigated extending to the infinite case some results in [6,7,8]. In particular, it is shown that any torsion-free or primary generalized soluble group with non-trivial cyclicizer is an F W -group. Moreover, the well-known characterization of finite p-groups with only one subgroup of order p (see, for instance, [9], 5.3.6) will be extended to locally finite groups. Finally, it is proved that the factor group G / C y c ( G ) is finite if and only if G has a finite covering of locally cyclic subgroups.
Most of our notation is standard and can be found in [10].

2. FW-Groups

Our first result is an easy remark concerning cyclic automorphisms of finite order.
Lemma 1.
Let G be a group. Every periodic cyclic automorphism of G is a power automorphism.
Proof. 
Let α be a cyclic automorphism of G, let g be an element of G, and consider a maximal locally cyclic subgroup M of G such that g M . As one can easily see that M α = M (see, for instance, in [3], Lemma 2.1), then the normal closure x α is locally cyclic and hence there exists an element x of G such that g α = x . Clearly, x α = x and we may suppose that g has infinite order. Therefore, x α = x 1 and g α = g 1 . Thus, α induces a power automorphism on G. □
Let G be a group. A normal subgroup W of G is said to be weakly central if every element of G induces by conjugation a cyclic automorphism of W. Clearly, if G contains a weakly central subgroup of finite index, then G is an F W -group.
Proposition 1.
Let G be a group. If W is a weakly central subgroup of finite index of G, then every subgroup of W is normal in G. In particular, G is an F P -group.
Proof. 
First, assume that every inner automorphism of G is cyclic. Then, G coincides with its cyclic norm and hence every maximal locally cyclic subgroup of G is normal. Let g be an element of G and consider a maximal locally cyclic subgroup M containing g. As G is an F C -group (see [3], Theorem 4.2), then the normal closure g G of g in G is a finitely generated subgroup of M. Therefore, g is normal in G and thus G is a Dedekind group.
The above argument shows that W is a Dedekind group. Since a cyclic automorphism of a periodic group is a power automorphism (see in [3], Lemma 2.3), we may suppose that W is abelian. It follows that the factor group G / C G ( W ) is finite and hence every element g of G induces on W a cyclic automorphism of finite order. The statement now follows from Lemma 1. □
Corollary 1.
Let G be a group all of whose inner automorphisms are cyclic automorphisms. Then G is a Dedekind group.
Let G be a group. We denote here with F P ( G ) the F P - c e n t r e of G, namely the subgroup of all elements of G inducing by conjugation power automorphisms on some subgroup of finite index of G. Clearly, F P ( G ) is a subgroup of F W ( G ) .
Recall that a non-periodic group is said to be weak if it can be generated by its elements of infinite order, while it is said to be strong otherwise. In particular, all non-periodic abelian groups are weak.
Theorem 1.
Let G be a group. Then, F W -centre and F P -centre of G coincide.
Proof. 
As the F P -centre of G is a subgroup of F W ( G ) , we just have to show that every element of G inducing a weakly cyclic automorphism of G induces a weakly power automorphism of G. Therefore, let g be an element of F W ( G ) and let W ( g ) be a normal subgroup of finite index of G such that g induces on W ( g ) a cyclic automorphism. By Lemma 1, we may assume that g induces an aperiodic automorphism on W ( g ) . Clearly, g n W ( g ) for some positive integer n and g n 1 . If W ( g ) is weak, then g acts universally on W ( g ) (see [3], Theorem 3.5) and then [ W ( g ) , g ] = { 1 } as g n belongs to W ( g ) , so we may further assume that W ( g ) is strong. If we let W be the subgroup of G generated by every element of infinite order of G, by Theorem 3.5 in [3], g fixes W and G / W elementwise. Let now x be an element of finite order of W ( g ) and let m be the order of x. As x and x g are both subgroups of order m of the cyclic group x , x g , they coincide and this shows that g acts as a power automorphism on every finite cyclic subgroup of W ( g ) . As g centralizes every element of infinite order of G, it follows that g induces a power automorphism on W ( g ) and our thesis is proved. □
Corollary 2.
Let G be a group. Then, G is an F W -group if and only if G is an F P -group.
Recall that a subgroup X of a group G is said to be pronormal if the subgroups X and X g are conjugate in the subgroup X , X g for all elements g of G. As any subnormal and pronormal subgroup of a group is normal, it follows that a group all of whose subgroups are pronormal is a T ¯ - g r o u p (i.e., a group in which normality is a transitive relation in every subgroup). However, the converse is false, as an example due to Kuzennyi and Subbotin [11] shows. We point out incidentally that in the universe of groups with no infinite simple sections the property T ¯ for a group G is equivalent to saying that every subgroup of G is weakly normal (see [12]). A tool which is useful to control pronormal subgroups of a group G is the p r o n o r m of G, which is defined as the set P ( G ) of all elements g of G such that X and X g are conjugate in X , X g for any subgroup X of G. The consideration of the alternating group A 5 shows that the pronorm of a group need not be in general a subgroup. On the other hand, the pronorm of a T ¯ -group G with no infinite simple sections is a subgroup of G which coincides with the set L ( G ) consisting of all elements g G such that, if H is a subgroup of G, then g normalizes a subgroup of finite index of H (see [13], Theorem 2.2). The last result of this section shows in particular that a T ¯ -group G with no infinite simple sections has all subgroups pronormal whenever G belongs to the class FW .
Corollary 3.
Let G be a group. Then, F W ( G ) is contained in L ( G ) . In particular, if G is a T ¯ -group with no infinite simple sections, F W ( G ) is a subgroup of P ( G ) .
Proof. 
By Theorem 1, for every element g of F W ( G ) we may find a normal subgroup W ( g ) of finite index of G on which g acts as a power automorphism. If we let H be a subgroup of G, then the subgroup H W ( g ) of W ( g ) is normalized by g, has finite index in H and this proves our claim. □

3. Groups with Non-Trivial Cyclicizer

It is straightforward to see that a group with non-trivial cyclicizer is either torsion-free or periodic. Therefore, it is natural to inspect the cases in which the groups are either torsion-free or primary groups. As some arguments can be unified, in the following elements of infinite order will be said elements of order 0 and torsion-free groups will be called 0- g r o u p s .
Lemma 2.
Let G be a p-group where p is a prime or 0. If the cyclicizer C y c ( G ) of G is not trivial, then it coincides with the centre Z ( G ) of G.
Proof. 
Assume for a contradiction that C y c ( G ) is a proper subgroup of Z ( G ) . Then, we may find an element x of G and an element y Z ( G ) such that x , y = x × y . Let now c be a non-trivial element of C y c ( G ) . As the subgroups x , c and y , c are cyclic, there is a power of c which belongs to x y = { 1 } . It follows that C y c ( G ) is periodic, so that also G is periodic and hence the subgroups x , c and y , c have a unique subgroup of order p for a prime p dividing the order of, say, x , c . In particular, the intersection x y is not trivial. This contradiction completes the proof. □
The consideration of the direct product of a group of order 3 and a dihedral group of order 8 shows that there exists a (finite) group G whose order is divided by only two primes and such that { 1 } C y c ( G ) < Z ( G ) .
Let A = a be a cyclic group of order 4, let B be a group of type 2 and let b be an element of order 4 of B. Consider the semidirect product H = A B where a acts as the inversion on B. Take K = a 2 b 2 and put G = H / K . Clearly, every finite non-abelian subgroup of G is a generalized quaternion group. Therefore, in analogy with the locally dihedral 2-group D 2 , we call G a locally generalized quaternion group and we denote it with Q 2 .
Here we give a first extension of Theorem 8 in [5].
Lemma 3.
Let G be a locally finite p-group for some prime p. Then, the cyclicizer of G is not trivial if and only if
(1)
G is locally cyclic or
(2)
G is isomorphic with a subgroup of Q 2 .
In particular, if G is finite and non-abelian, then G is a generalized quaternion group.
Proof. 
Assume that the cyclicizer C of G contains a non-trivial element c of order p. If G is abelian, then Lemma 2 yields that G coincides with its cyclicizer and then G is locally cyclic. Assume thus that there exists a finite non-abelian subgroup H of G and let x be an element of H , c of order p. As x , c is cyclic, one has that x is a power of c, namely H , c contains a unique subgroup of order p. By a well-known characterization (see, for instance, [9], 5.3.6) we have that H , c is a generalized quaternion group. As this property holds for every finite subgroup of G containing H , c and the set of finite subgroups of G containing H , c is a direct system of G, we can clearly assume that G is infinite. Therefore, it is possible to find in G a subgroup Q which is isomorphic with Q 2 . Let g be any element of G, let P be the Prüfer 2-subgroup of Q and let y be an element of order n > 4 of P. As g , y = g , y , c is either a cyclic or a generalized quaternion group, we have in any case that y is normalized by g and hence the whole P is normalized by g. Moreover, g has non-trivial intersection with P, as both must contain c. Then, g has to be contained in Q, otherwise g , Q would contain a direct product of two cyclic subgroups of order 2. From this it immediately follows that G is isomorphic with Q 2 .
Let us prove the converse. If G is locally cyclic the result is clear. On the other hand, take G to be a subgroup of Q 2 which is not locally cyclic. Then, G is not abelian, so that it is either the whole Q 2 or a generalized quaternion group. In both cases Z ( G ) is the only subgroup of G of order 2 and therefore it coincides with the cyclicizer of G, which is then non-trivial. □
This result gives a generalization to the locally finite case of the already quoted result about finite p-groups [9], 5.3.6.
Corollary 4.
Let p be a prime. A locally finite p-group G contains exactly one subgroup of order p if and only if it satisfies one of the following conditions:
(1)
G is locally cyclic;
(2)
G is isomorphic with a generalized quaternion group;
(3)
G is isomorphic with Q 2 .
In [7], it is proved that if G is a torsion-free group such that cyclicizer C y c ( G ) is not trivial, then C y c ( G ) = Z ( G ) and if Z ( G ) is divisible, then G is locally cyclic. One may ask whether a torsion-free or a p-group with non-trivial cyclicizer is locally cyclic. In general, these questions can be answered in the negative because of two results by Olšanskiĭ (see in [14], Theorem 31.4 and Theorem 31.5). On the other hand, our next result shows that for a wide class of generalized soluble groups the statement is true.
A group G is said to be weakly radical if it contains an ascending (normal) series all of whose factors are either locally soluble or locally finite.
Theorem 2.
Let G be a locally weakly radical group such that | π ( G ) | 1 . Then, G has non-trivial cyclicizer if and only if
(1)
G is locally cyclic or
(2)
G is isomorphic with a subgroup of Q 2 .
Proof. 
Let C be the cyclicizer of G. If C { 1 } , it follows from Lemma 2 that C = Z ( G ) . Moreover, as already pointed out, G is either torsion-free or periodic. By Lemma 3, we may also suppose that G is torsion-free. Let c be a non-trivial element of C. If x is an element of G, then the subgroup E = x , c of G is cyclic and hence there exists a positive integer n such that x n belongs to c . Thus the factor group G / C is periodic and so even locally finite since G is locally weakly radical. Now an easy application of a famous theorem by Schur (see, for instance, Corollary to Theorem 4.12 in [10]) shows that the commutator subgroup of G is locally finite and hence G is abelian. In particular, G is locally cyclic.
The converse is an immediate consequence of Lemma 3. □
Corollary 5.
Let G be a locally weakly radical group such that | π ( G ) | 1 . If G has non-trivial cyclicizer, then it is an F W -group.
A straightforward application of Theorem 2 and of [9], 12.1.1 is the following.
Corollary 6.
Let G be a locally nilpotent group. Then G has non-trivial cyclicizer if and only if either it is locally cyclic or G is periodic and there is a prime number p such that the p-component G p of G either is locally cyclic or is isomorphic with a subgroup of Q 2 .
A well-known result of Baer (see, for instance, in [10], Theorem 4.16) states that a group is central-by-finite if and only if it has a finite covering consisting of abelian subgroups. Furthermore, we have already quoted the theorem by Schur that ensures that a central-by-finite group is finite-by-abelian. In the following we rephrase these results replacing the centre Z ( G ) of G by the cyclicizer C y c ( G ) . Recall that a collection Σ of subgroups of a group G is said to be a covering of G if each element of G belongs to at least one subset in Σ .
Theorem 3.
Let G be a group and let C be the cyclicizer of G. Then, the following hold:
(1)
If C has finite index in G, then G is finite-by-(locally cyclic);
(2)
The factor group G / C is finite if and only if G has a finite covering consisting of locally cyclic subgroups.
Proof. 
(1) As C Z ( G ) , then G is central-by-finite and hence the commutator subgroup G of G is finite. Clearly, we may assume that G is infinite, so that C too is infinite and, by replacing G with G / G , we may suppose that G is abelian. Moreover, as C is non-trivial, then G is either torsion-free or periodic. In the former case, G is locally cyclic by Proposition 2. Assume hence that G is periodic. In this case, as we aim to show that G is locally cyclic, we may also suppose that G is a p-group for a prime p. However, C is locally cyclic and hence of type p . It follows that G can be decomposed as G = C × H where H is a subgroup of G. If c and h are elements of order p of C and H, respectively, then the subgroup c , h is not cyclic. This contradiction shows that H is trivial and hence G = C is locally cyclic.
(2) First assume that the factor group G / C is finite. Choose a (left) transversal to C in G, say { x 1 , , x n } . Then, for any element g of G, we can write g = x i c where c is an element of C. Therefore, g belongs to x i , C , which is locally cyclic, and G is covered by the subgroups x i , C with i = 1 , , n .
Conversely, assume that G is covered by finitely many locally cyclic subgroups. Then by a result of Neumann (see in [10], Lemma 4.17) G is covered by finitely many locally cyclic subgroups of finite index. Let L be their intersection. Clearly, L is contained in C and | G : L | is finite. It follows that G / C is finite. □
We remark that the cyclicizer of the direct product of Z 2 × Q is trivial, so that the converse of point (1) of Theorem 3 is not true.

Author Contributions

Conceptualization, M.B. and A.R.; methodology, M.B. and A.R.; software, M.B. and A.R.; validation, M.B. and A.R.; formal analysis, M.B. and A.R.; investigation, M.B. and A.R.; resources, M.B. and A.R.; data curation, M.B. and A.R.; writing—original draft preparation, M.B. and A.R.; writing—review and editing, M.B. and A.R.; visualization, M.B. and A.R.; supervision, M.B. and A.R.; project administration, M.B. and A.R.; funding acquisition, M.B. and A.R. All authors have read and agreed to the published version of the manuscript.

Funding

This work was carried out within the “V:Valere 2019:Project: GoAL: VALERE: VAnviteLli pEr la RicErca”.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors are supported by the “VALERE: VAnviteLli pEr la RicErca” project, by GNSAGA (INdAM) and are members of the non-profit association “Advances in Group Theory and Applications”.

Conflicts of Interest

The authors declare no conflict of interest.

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Brescia, M., & Russo, A. (2022). On Groups in Which Many Automorphisms Are Cyclic. Mathematics, 10(2), 262. https://doi.org/10.3390/math10020262

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