Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-16T21:16:05.626Z Has data issue: false hasContentIssue false

On the commuting probability for subgroups of a finite group

Published online by Cambridge University Press:  18 November 2021

Eloisa Detomi
Affiliation:
Dipartimento di Ingegneria dell'Informazione – DEI, Università di Padova, Via G. Gradenigo 6/B, Padova 35121, Italy ([email protected])
Pavel Shumyatsky
Affiliation:
Department of Mathematics, University of Brasilia, Brasilia, DF 70910-900, Brazil ([email protected])
Rights & Permissions [Opens in a new window]

Abstract

Let $K$ be a subgroup of a finite group $G$. The probability that an element of $G$ commutes with an element of $K$ is denoted by $Pr(K,G)$. Assume that $Pr(K,G)\geq \epsilon$ for some fixed $\epsilon >0$. We show that there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$ and the order of the commutator subgroup $[T,B]$ are $\epsilon$-bounded. This extends the well-known theorem, due to P. M. Neumann, that covers the case where $K=G$. We deduce a number of corollaries of this result. A typical application is that if $K$ is the generalized Fitting subgroup $F^{*}(G)$ then $G$ has a class-2-nilpotent normal subgroup $R$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $\epsilon$-bounded. In the same spirit we consider the cases where $K$ is a term of the lower central series of $G$, or a Sylow subgroup, etc.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

1. Introduction

The probability that two randomly chosen elements of a finite group $G$ commute is given by

\[ Pr(G)=\frac{|\{(x,y)\in G\times G\ :\ xy=yx \}|}{|G|^{2}}. \]

The above number is called the commuting probability (or the commutativity degree) of $G$. This is a well-studied concept. In the literature one can find publications dealing with problems on the set of possible values of $Pr(G)$ and the influence of $Pr(G)$ over the structure of $G$ (see [Reference Eberhard9, Reference Guralnick and Robinson15, Reference Gustafson17, Reference Lescot22, Reference Lescot23] and references therein). The reader can consult [Reference Mann25, Reference Shalev32] and references therein for related developments concerning probabilistic identities in groups.

P. M. Neumann [Reference Neumann29] proved the following theorem (see also [Reference Eberhard9]).

Theorem 1.1 Let $G$ be a finite group and let $\epsilon$ be a positive number such that $Pr(G)\geq \epsilon$. Then $G$ has a nilpotent normal subgroup $R$ of nilpotency class at most $2$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $\epsilon$-bounded.

Throughout the article we use the expression ‘$(a,b,\dots )$-bounded’ to mean that a quantity is bounded from above by a number depending only on the parameters $a,b,\dots$.

If $K$ is a subgroup of $G$, write

\[ Pr(K,G)=\frac{|\{(x,y)\in K\times G\ :\ xy=yx \}|}{|K||G|}. \]

This is the probability that an element of $G$ commutes with an element of $K$ (the relative commutativity degree of $K$ in $G$).

This notion has been studied in several recent papers (see in particular [Reference Erfanian, Rezaei and Lescot10, Reference Nath and Yadav26]). Here we will prove the following proposition.

Proposition 1.2 Let $K$ be a subgroup of a finite group $G$ and let $\epsilon$ be a positive number such that $Pr(K,G)\geq \epsilon$. Then there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$, and the order of the commutator subgroup $[T,B]$ are $\epsilon$-bounded.

Theorem 1.1 can be easily obtained from the above result taking $K=G$.

Proposition 1.2 has some interesting consequences. In particular, we will establish the following results.

Recall that the generalized Fitting subgroup $F^{*}(G)$ of a finite group $G$ is the product of the Fitting subgroup $F(G)$ and all subnormal quasisimple subgroups; here a group is quasisimple if it is perfect and its quotient by the centre is a non-abelian simple group. Throughout, by a class-$c$-nilpotent group we mean a nilpotent group whose nilpotency class is at most $c$.

Theorem 1.3 Let $G$ be a finite group such that $Pr(F^{*}(G),G)\geq \epsilon$, where $\epsilon$ is a positive number. Then $G$ has a class-$2$-nilpotent normal subgroup $R$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $\epsilon$-bounded.

A somewhat surprising aspect of the above theorem is that information on the commuting probability of a subgroup (in this case $F^{*}(G)$) enables one to draw a conclusion about $G$ as strong as in P. M. Neumann's theorem. Yet, several other results with the same conclusion will be established in this paper.

Our next theorem deals with the case where $K$ is a subgroup containing $\gamma _i(G)$ for some $i\geq 1$. Here and throughout the paper $\gamma _i(G)$ denotes the $i$th term of the lower central series of $G$.

Theorem 1.4 Let $K$ be a subgroup of a finite group $G$ containing $\gamma _i(G)$ for some $i\geq 1$. Suppose that $Pr(K,G)\geq \epsilon$, where $\epsilon$ is a positive number. Then $G$ has a nilpotent normal subgroup $R$ of nilpotency class at most $i+1$ such that both the index $[G:R]$ and the order of $\gamma _{i+1}(R)$ are $\epsilon$-bounded.

P. M. Neumann's theorem is a particular case of the above result (take $i=1$).

In the same spirit, we conclude that $G$ has a nilpotent subgroup of $\epsilon$-bounded index if $K$ is a verbal subgroup corresponding to a word implying virtual nilpotency such that $Pr(K,G)\geq \epsilon$. Given a group-word $w$, we write $w(G)$ for the corresponding verbal subgroup of a group $G$, that is the subgroup generated by the values of $w$ in $G$. Recall that a group-word $w$ is said to imply virtual nilpotency if every finitely generated metabelian group $G$ where $w$ is a law, that is $w(G)=1$, has a nilpotent subgroup of finite index. Such words admit several important characterizations (see [Reference Black2, Reference Burns and Medvedev4, Reference Groves12]). In particular, by a result of Gruenberg [Reference Gruenberg13], the $j$-Engel word $[x,y,\dots,y]$, where $y$ appears $j \ge 1$ times, implies virtual nilpotency. Burns and Medvedev proved that for any word $w$ implying virtual nilpotency there exist integers $e$ and $c$ depending only on $w$ such that every finite group $G$, in which $w$ is a law, has a class-$c$-nilpotent normal subgroup $N$ such that $G^{e}\leq N$ [Reference Burns and Medvedev4]. Here $G^{e}$ denotes the subgroup generated by all $e$th powers of elements of $G$. Our next theorem provides a probabilistic variation of this result.

Theorem 1.5 Let $w$ be a group-word implying virtual nilpotency. Suppose that $K$ is a subgroup of a finite group $G$ such that $w(G)\leq K$ and $Pr(K,G)\geq \epsilon$, where $\epsilon$ is a positive number. There is an $(\epsilon,w)$-bounded integer $e$ and a $w$-bounded integer $c$ such that $G^{e}$ is nilpotent of class at most $c$.

We also consider finite groups with a given value of $Pr(P,G)$, where $P$ is a Sylow $p$-subgroup of $G$.

Theorem 1.6 Let $P$ be a Sylow $p$-subgroup of a finite group $G$ such that $Pr(P,G) \ge \epsilon$, where $\epsilon$ is a positive number. Then $G$ has a class-$2$-nilpotent normal $p$-subgroup $L$ such that both the index $[P:L]$ and the order of $[L,L]$ are $\epsilon$-bounded.

Once we have information on the commuting probability of all Sylow subgroups of $G$, the result is as strong as in P. M. Neumann's theorem.

Theorem 1.7 Let $\epsilon >0$, and let $G$ be a finite group such that $Pr(P,G) \ge \epsilon$ whenever $P$ is a Sylow subgroup. Then $G$ has a nilpotent normal subgroup $R$ of nilpotency class at most $2$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $\epsilon$-bounded.

If $\phi$ is an automorphism of a group $G$, the centralizer $C_G(\phi )$ is the subgroup formed by the elements $x\in G$ such that $x^{\phi }=x$. In the case where $C_G(\phi )=1$ the automorphism $\phi$ is called fixed-point-free. A famous result of Thompson [Reference Thompson33] says that a finite group admitting a fixed-point-free automorphism of prime order is nilpotent. Higman proved that for each prime $p$ there exists a number $h=h(p)$ depending only on $p$ such that whenever a nilpotent group $G$ admits a fixed-point-free automorphism of order $p$, it follows that $G$ has nilpotency class at most $h$ [Reference Higman19]. Therefore a finite group admitting a fixed-point-free automorphism of order $p$ is nilpotent of class at most $h$. Khukhro obtained the following ‘almost fixed-point-free’ generalization of this fact [Reference Khukhro21]: if a finite group $G$ admits an automorphism $\phi$ of prime order $p$ such that $C_G(\phi )$ has order $m$, then $G$ has a nilpotent subgroup of $p$-bounded nilpotency class and $(m,p)$-bounded index. We will establish a probabilistic variation of the above results. Recall that an automorphism $\phi$ of a finite group $G$ is called coprime if $(|G|,|\phi |)=1$.

Theorem 1.8 Let $G$ be a finite group admitting a coprime automorphism $\phi$ of prime order $p$ such that $Pr(C_G(\phi ),G)\geq \epsilon$ where $\epsilon$ is a positive number. Then $G$ has a nilpotent subgroup of $p$-bounded nilpotency class and $(\epsilon,p)$-bounded index.

An even stronger conclusion will be derived about groups admitting an elementary abelian group of automorphisms of rank at least 2.

Theorem 1.9 Let $\epsilon >0$, and let $G$ be a finite group admitting an elementary abelian coprime group of automorphisms $A$ of order $p^{2}$ such that $Pr(C_G(\phi ),G)\geq \epsilon$ for each nontrivial $\phi \in A$. Then $G$ has a class-$2$-nilpotent normal subgroup $R$ such that both the index $[G:R]$ and the order of $[R,R]$ are $(\epsilon,p)$-bounded.

Proposition 1.2, which is a key result of this paper, will be proved in the next section. The other results will be established in § 35.

2. The key result

A group is said to be a BFC-group if its conjugacy classes are finite and of bounded size. A famous theorem of B. H. Neumann says that in a BFC-group the commutator subgroup $G'$ is finite [Reference Neumann27]. It follows that if $|x^{G}|\leq m$ for each $x\in G$, then the order of $G'$ is bounded by a number depending only on $m$. A first explicit bound for the order of $G'$ was found by J. Wiegold [Reference Wiegold34], and the best known was obtained in [Reference Guralnick and Maroti16] (see also [Reference Neumann and Vaughan-Lee28] and [Reference Segal and Shalev31]). The main technical tools employed in this paper are provided by the recent results [Reference Acciarri and Shumyatsky1, Reference Detomi, Morigi and Shumyatsky6Reference Dierings and Shumyatsky8] strengthening B. H. Neumann's theorem.

A well-known lemma due to Baer says that if $A,B$ are normal subgroups of a group $G$ such that $[A:C_A(B)]\leq m$ and $[B:C_B(A)]\leq m$ for some integer $m\geq 1$, then $[A,B]$ has finite $m$-bounded order (see [Reference Robinson30, 14.5.2]).

We will require a stronger result. Here and in the rest of the paper, given an element $x\in G$ and a subgroup $H\leq G$, we write $x^{H}$ for the set of conjugates of $x$ by elements from $H$.

Lemma 2.1 Let $m\geq 1$, and let $G$ be a group containing normal subgroups $A,B$ such that $[A:C_A(y)]\leq m$ and $[B:C_B(x)]\leq m$ for all $x\in A$, $y\in B$. Then $[A,B]$ has finite $m$-bounded order.

Proof. We first prove that, given $x\in A$ and $y\in B$, the order of $[x,y]$ is $m$-bounded. Let $H=\langle x,y\rangle$. By assumptions, $[A:C_A(y)]\leq m$ and $[B:C_B(x)]\leq m$. Hence there exists an $m$-bounded number $l$ such that $x^{l}$ and $y^{l}$ are contained in $Z(H)$ (e.g. we can take $l=m!$). Let $D=A\cap B \cap H$ and $N=\langle D,x^{l},y^{l}\rangle$. Then $H/N$ is abelian of order at most $l^{2}$. Both $x$ and $y$ have centralizers of index at most $m$ in $N$. Moreover every element of $N$ has centralizer of index at most $m$ in $N$. Indeed $|d^{N}| \le |d^{A}|\le m$ for every $d \in D \le A\cap B$. So, every element of $H$ is a product of at most $l^{2}+1$ elements each of which has centralizer of index at most $m$ in $N$. Therefore each element of $H$ has centralizer of $m$-bounded index in $H$. We conclude that $H$ is a BFC-group in which the sizes of conjugacy classes are $m$-bounded. Hence $|H'|$ is $m$-bounded and so the order of $[x,y]$ is $m$-bounded, too.

Now we claim that for every $x \in A$, the subgroup $[x,B]$ has finite $m$-bounded order. Indeed, $x$ has at most $m$ conjugates $\{x^{b_1}, \dots, x^{b_m} \}$ in $B$, where $b_1, \dots, b_m \in B$, so $[x,B]$ is generated by at most $m$ elements. Let $C$ be a maximal normal subgroup of $B$ contained in $C_B(x)$. Clearly $C$ has $m$-bounded index in $B$ and centralizes $[x,B]$. Thus, the centre of $[x,B]$ has $m$-bounded index in $[x,B]$. It follows from Schur's theorem [Reference Robinson30, 10.1.4] that the derived subgroup of $[x,B]$ has finite $m$-bounded order. Since $[x,B]$ is generated by at most $m$ elements of $m$-bounded order, we deduce that the order of $[x,B]$ is finite and $m$-bounded.

Choose $a\in A$ such that $[B:C_B(a)]=\max _{x \in A} [B:C_B(x)]$ and set $n=[B:C_B(a)]$, where $n \le m$. Let $b_1,\dots, b_n$ be elements of $B$ such that $a^{B}=\{a^{b_1},\dots, a^{b_n}\}$ is the set of (distinct) conjugates of $a$ by elements of $B$. Set $U=C_A(b_1,\dots,b_n)$ and note that $U$ has $m$-bounded index in $A$. Given $u\in U$, the elements $(ua)^{b_1},\dots, (ua)^{b_n}$ form the conjugacy class $(ua)^{B}$ because they are all different and their number is the allowed maximum. So, for an arbitrary element $y\in B$ there exists $i$ such that $(ua)^{y}=(ua)^{b_i}=u a^{b_i}$. It follows that $u^{-1}u^{y}=a^{b_i}a^{-y}$, hence

\[ [u,y]=a^{b_i}a^{{-}y} =[a, b_i^{a^{{-}1}}][ y^{a^{{-}1}},a] \in [a, B]. \]

Therefore $[U,B]\leq [a,B]$. Let $a_1,\dots,a_s$ be coset representatives of $U$ in $A$ and note that $s$ is $m$-bounded. As each $[x,B]$ is normal in $B$ and $[U,B]\leq [a,B]$, we deduce that $[A,B]=[a,B]\prod [a_i,B]$. So $[A,B]$ is a product of $m$-boundedly many subgroups of $m$-bounded order. These subgroups are normal in $B$ and therefore their product has finite $m$-bounded order.

In the next lemma the subgroup $B$ is not necessarily normal. Instead, we require that $B$ is contained in an abelian normal subgroup. Throughout, $\langle H^{G}\rangle$ denotes the normal closure of a subgroup $H$ in $G$.

Lemma 2.2 Let $m\geq 1$, and let $G$ be a group containing a normal subgroup $A$ and a subgroup $B$ such that $[A:C_A(y)]\leq m$ and $[B:C_B(x)]\leq m$ for all $x\in A$, $y\in B$. Assume further that $\langle B^{G}\rangle$ is abelian. Then $[A, B]$ has finite $m$-bounded order.

Proof. Without loss of generality we can assume that $G=AB$. Set $L=\langle B^{G}\rangle =\langle B^{A}\rangle$.

Let $x\in A$. There is an $m$-bounded number $l$ such that $x$ centralizes $y^{l}$ for every $y\in B$. Since $L$ is abelian, $[x,y]^{i}=[x,y^{i}]$ for each $i$ and therefore the order of $[x,y]$ is at most $l$. Thus $[x,B]$ is an abelian subgroup generated by at most $m$ elements of $m$-bounded order, whence $[x,B]$ has finite $m$-bounded order.

Now we choose $a\in A$ such that $[B:C_B(a)]$ is as big as possible. Let $b_1,\dots,b_{m}$ be elements of $B$ such that $a^{B}=\{a^{b_1},\dots,a^{b_{m}}\}$. Set $U=C_A(b_1,\dots,b_m)$ and note that $U$ has $m$-bounded index in $A$. Arguing as in the previous lemma, we see that for arbitrary $u\in U$ and $y\in B$, the conjugate $(ua)^{y}$ belongs to the set $\{(ua)^{b_1},\dots, (ua)^{b_m}\}$. Let $(ua)^{y}=(ua)^{b_i}$. Then $u^{-1}u^{y}=a^{b_i}a^{-y}$ and hence $[u,y]=a^{b_i}a^{-y}\in [a, B]$. Therefore $[U,B]\leq [a,B]$.

Let $V=\cap _{x\in A}U^{x}$ be the maximal normal subgroup of $A$ contained in $U$. We know that $[V,B]$ has $m$-bounded order, since $[V,B]\le [a,B]$. Denote the index $[A:V]$ by $s$. Evidently, $s$ is $m$-bounded. Let $a_1,\dots,a_s$ be a transversal of $V$ in $A$. As $[V,B] \le L=\langle B^{A}\rangle$ is abelian, we have

\[ \langle[V,B]^{G}\rangle=\langle[V,B]^{A}\rangle=\prod_{i=1}^{s}[V,B]^{a_i}. \]

Thus $[V,L]=[V, B^{A}] = \langle [V,B]^{A}\rangle$ is a product of $m$-boundedly many subgroups of $m$-bounded order, and hence it has $m$-bounded order. Write

\[ L=\langle B^{A}\rangle \leq \langle B^{V a_i} \mid i=1, \dots s \rangle \leq [V,L]\prod_{i=1}^{s}B^{a_i}. \]

Thus, it becomes clear that $L$ is a product of $m$-boundedly many conjugates of $B$. Say $L$ is a product of $t$ conjugates of $B$. Then, every $y \in L$ can be written as a product of at most $t$ conjugates of elements of $B$ and consequently $[A: C_A(y)] \le m^{t}.$ Moreover, as $A$ is normal in $G$ and $|a^{B}| \le m$ for every $a\in A$, the conjugacy class $x^{L}$ of an element $x \in A$ has size at most $m^{t}$. Now lemma 2.1 shows that $[A,B] \le [A,L]$ has finite $m$-bounded order.

We will now show that if $K$ is a subgroup of a finite group $G$ and $N$ is a normal subgroup of $G$, then $Pr(KN/N,G/N)\geq Pr(K,G)$. More precisely, we will establish the following lemma.

Lemma 2.3 Let $N$ be a normal subgroup of a finite group $G$, and let $K\leq G$. Then $Pr(K,G)\leq Pr(KN/N,G/N)Pr(N\cap K,N)$.

This is an improvement over [Reference Erfanian, Rezaei and Lescot10, theorem 3.9] where the result was obtained under the additional hypothesis that $N\leq K$.

Proof. In what follows $\bar {G}=G/N$ and $\bar {K}=KN/N$. Write $\bar {K_0}$ for the set of cosets $(N\cap K)h$ with $h\in K$. If $S_0=(N\cap K)h\in \bar {K_0}$, write $S$ for the coset $Nh\in \bar {K}$. Of course, we have a natural one-to-one correspondence between $\bar {K_0}$ and $\bar {K}$.

Write

\begin{align*} |K||G|Pr(K,G)&=\sum_{x\in K}|C_G(x)|=\sum_{S_0\in\bar{K_0}}\sum_{x\in S_0}\frac{|C_G(x)N|}{|N|}|C_N(x)|\\ &\leq\sum_{S_0\in\bar{K_0}}\sum_{x\in S_0}|C_{\bar{G}}(xN)||C_N(x)|=\sum_{S\in\bar{K}}|C_{\bar{G}}(S)|\sum_{x\in S_0}|C_N(x)|\\ &=\sum_{S\in\bar{K}}|C_{\bar{G}}(S)|\sum_{y\in N}|C_{S_0}(y)|.\\ \end{align*}

If $C_{S_0}(y)\neq \emptyset$, then there is $y_0\in C_{S_0}(y)$ and so $S_0=(N\cap K)y_0$. Therefore

\[ C_{S_0}(y)=(N\cap K)y_0\cap C_G(y)=C_{N\cap K}(y)y_0,\quad\text{whence}\ |C_{S_0}(y)|=|C_{N\cap K}(y)|. \]

Conclude that

\[ |K||G|Pr(K,G)\leq \sum_{S\in\bar{K}}|C_{\bar{G}}(S)|\sum_{y\in N}|C_{N\cap K}(y)|. \]

Observe that

\[ \sum_{S\in\bar{K}}|C_{\bar{G}}(S)|=\frac{|K|}{|N\cap K|}\frac{|G|}{|N|}Pr(\bar{K},\bar{G}) \]

and

\[ \sum_{y\in N}|C_{N\cap K}(y)|=|N\cap K||N|Pr(N\cap K,N). \]

It follows that $Pr(K,G)\leq Pr(\bar {K},\bar {G})Pr(N\cap K,N)$, as required.

The following theorem is taken from [Reference Acciarri and Shumyatsky1]. It plays a crucial role in the proof of proposition 1.2.

Theorem 2.4 Let $m$ be a positive integer, $G$ a group having a subgroup $K$ such that $|x^{G}| \le m$ for each $x\in K$, and let $H=\langle K^{G}\rangle$. Then the order of the commutator subgroup $[H,H]$ is finite and $m$-bounded.

A proof of the next lemma can be found in Eberhard [Reference Eberhard9, lemma 2.1].

Lemma 2.5 Let $G$ be a finite group and $X$ a symmetric subset of $G$ containing the identity. Then $\langle X \rangle = X^{3r}$ provided $(r+1)|X| > |G|$.

We are now ready to prove proposition 1.2 which we restate here for the reader's convenience:

Let $\epsilon >0$, and let $G$ be a finite group having a subgroup $K$ such that $Pr(K,G)\geq \epsilon$. Then there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$ and the order of $[T,B]$ are $\epsilon$-bounded.

Proof of proposition 1.2. Set

\[ X=\{x\in K \mid |x^{G}|\leq 2/\epsilon\}\quad \text{and}\quad B=\langle X\rangle. \]

Note that $K \setminus X=\{ x\in K \mid |C_G(x)|\leq (\epsilon /2) |G| \}$, whence

\begin{align*} \epsilon |K||G| &\le | \{ (x,y) \in K\times G \mid xy=yx \} |=\sum_{x\in K}|C_G(x)|\\ &\le \sum_{x \in X} |G| + \sum_{x \in K \setminus X} \frac{\epsilon}{2} |G|\\ &\le |X| |G| +(|K| - |X|)\frac{\epsilon}{2}|G|. \end{align*}

Therefore $\epsilon |K| \le |X|+ ({\epsilon }/{2}) (|K| - |X|)$, whence $({\epsilon }/{2}) |K| < |X|$. Clearly, $|B| \ge |X| > ({\epsilon }/{2}) |K|$ and so the index of $B$ in $K$ is at most $2/\epsilon$. As $X$ is symmetric and $(2/\epsilon ) |X| > |K|$, it follows from lemma 2.5 that every element of $B$ is a product of at most $6/\epsilon$ elements of $X$. Therefore $|b^{G}| \le (2/\epsilon )^{6/\epsilon }$ for every $b \in B$.

Let $L=\langle B^{G}\rangle$. Theorem 2.4 tells us that the commutator subgroup $[L,L]$ has $\epsilon$-bounded order. Let us use the bar notation for the images of the subgroups of $G$ in $G/[L,L]$. By lemma 2.3,

\[ Pr(\bar K, \bar G) \ge Pr(K,G)\geq\epsilon. \]

Moreover, $[\bar K: \bar B] \le [K:B] \le {\epsilon }/{2}$ and $|\bar b^{ \bar G}| \le |b^{G}| \le (2/\epsilon )^{6/\epsilon }$. Thus we can pass to the quotient over $[L,L]$ and assume that $L$ is abelian.

Now we set

\[ Y= \{ y \in G \mid |y^{K}| \le 2/\epsilon\} = \{ y \in G \mid |C_K(y)| \ge ({\epsilon}/{2}) |K|\}. \]

Note that

\begin{align*} \epsilon |K||G| & \le | \{ (x,y) \in K \times G \mid xy=yx \} |\\ &\le \sum_{y \in Y} |K| + \sum_{y \in G \setminus Y} \frac{\epsilon}{2} |K|\\ &\le |Y| |K| +(|G| - |Y|)\frac{\epsilon}{2}|K| \le |Y| |K|+\frac{\epsilon}{2}|G| |K|. \end{align*}

Therefore $({\epsilon }/{2}) |G| < |Y|.$

Set $E= \langle Y \rangle$. Thus $|E| \ge |Y| > ({\epsilon }/{2}) |G|$, and so the index of $E$ in $G$ is at most $2/\epsilon$. As $Y$ is symmetric and $(2/\epsilon ) |Y| > |G|$, it follows from lemma 2.5 that every element of $E$ is a product of at most $6/\epsilon$ elements of $Y$. Since $|y^{K}|\le 2/\epsilon$ for every $y\in Y$, we conclude that $|e^{K}|\le (2/\epsilon )^{6/\epsilon }$ for every $e\in E$. Let $T$ be the maximal normal subgroup of $G$ contained in $E$. Clearly, the index $[G:T]$ is $\epsilon$-bounded.

So, now $|b^{G}| \le (2/\epsilon )^{6/\epsilon }$ for every $b \in B$ and $|e^{B}| \le (2/\epsilon )^{6/\epsilon }$ for every $e\in T$. As $L$ is abelian, we can apply lemma 2.2 to conclude that $[T,B]$ has $\epsilon$-bounded order and the result follows.

Remark 2.6 Under the hypotheses of proposition 1.2 the subgroup $N=\langle [T,B]^{G}\rangle$ has $\epsilon$-bounded order.

Proof. Since $[T,B]$ is normal in $T$, it follows that there are only boundedly many conjugates of $[T,B]$ in $G$ and they normalize each other. Since $N$ is the product of those conjugates, $N$ has $\epsilon$-bounded order.

As usual, $Z_i(G)$ stands for the $i$th term of the upper central series of a group $G$.

Remark 2.7 Assume the hypotheses of proposition 1.2. If $K$ is normal, then the subgroup $T$ can be chosen in such a way that $K\cap T\leq Z_3(T)$.

Proof. According to remark 2.6, $N=\langle [T,B]^{G}\rangle$ has $\epsilon$-bounded order. Let $B_0=\langle B^{G}\rangle$ and note that $B_0 \le K$ and $[T,B_0]\leq N$. Since the index $[K:B_0]$ and the order of $N$ are $\epsilon$-bounded, the stabilizer in $T$ of the series

\[ 1\leq N\leq B_0\leq K, \]

that is, the subgroup

\[ H=\{g\in T\ \vert\ [N,g]=1\ \& \ [K,g]\leq B_0\} \]

has $\epsilon$-bounded index in $G$. Note that $K\cap H\leq Z_3(H)$, whence the result.

3. Probabilistic almost nilpotency of finite groups

Our first goal in this section is to furnish a proof of theorem 1.3. We restate it here.

Let $G$ be a finite group such that $Pr(F^{*}(G),G)\geq \epsilon$. Then $G$ has a class- $2$-nilpotent normal subgroup $R$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $\epsilon$-bounded.

As mentioned in the introduction, the above result yields a conclusion about $G$ which is as strong as in P. M. Neumann's theorem.

Proof of Theorem 1.3. Set $K=F^{*}(G)$. In view of proposition 1.2 there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$, and the order of the commutator subgroup $[T,B]$ are $\epsilon$-bounded. As $K$ is normal in $G$, according to remark 2.7 the subgroup $T$ can be chosen in such a way that $K\cap T\leq Z_3(T)$. By [Reference Huppert and Blackburn20, corollary X.13.11(c)] we have $K\cap T=F^{*}(T)$. Therefore $F^{*}(T)\leq Z_3(T)$ and in view of [Reference Huppert and Blackburn20, theorem X.13.6] we conclude that $T=F^{*}(T)$ and so $T\leq K$. It follows that the index of $K$ in $G$ is $\epsilon$-bounded. By remark 2.6 the subgroup $N=\langle [T,B]^{G}\rangle$ has $\epsilon$-bounded order. Conclude that $R=\langle B^{G}\rangle \cap C_G(N)$ has $\epsilon$-bounded index in $G$. Moreover $R$ is nilpotent of class at most 2 and $[R,R]$ has $\epsilon$-bounded order. This completes the proof.

Now focus on theorem 1.4, which deals with the case where $\gamma _i(G)\leq K$. Start with a couple of remarks on the result. Let $G$ and $R$ be as in theorem 1.4. The fact that both the index $[G:R]$ and the order of $\gamma _{i+1}(R)$ are $\epsilon$-bounded implies that for any $x_1,\dots,x_i\in R$ the centralizer of the long commutator $[x_1,\dots,x_i]$ has $\epsilon$-bounded index in $G$. Therefore there is an $\epsilon$-bounded number $e$ such that $G^{e}$ centralizes all commutators $[x_1,\dots,x_i]$ where $x_1,\dots,x_i\in R$. Then $G_0=G^{e}\cap R$ is a nilpotent normal subgroup of nilpotency class at most $i$ with $G/G_0$ of $\epsilon$-bounded exponent (recall that a positive integer $e$ is the exponent of a finite group $G$ if $e$ is the minimal number for which $G^{e}=1$).

If $G$ is additionally assumed to be $m$-generated for some $m\geq 1$, then $G$ has a nilpotent normal subgroup of nilpotency class at most $i$ and $(\epsilon,m)$-bounded index. Indeed, we know that for any $x_1,\dots,x_i\in R$ the centralizer of the long commutator $[x_1,\dots,x_i]$ has $\epsilon$-bounded index in $G$. An $m$-generated group has only $(j,m)$-boundedly many subgroups of any given index $j$ [Reference Hall18, theorem 7.2.9]. Therefore $G$ has a subgroup $J$ of $(\epsilon,m)$-bounded index that centralizes all commutators $[x_1,\dots,x_i]$ with $x_1,\dots,x_i\in R$. Then $J\cap R$ is a nilpotent normal subgroup of nilpotency class at most $i$ and $(\epsilon,m)$-bounded index in $G$.

These observations are in parallel with Shalev's results on probabilistically nilpotent groups [Reference Shalev32].

Our proof of theorem 1.4 requires the following result from [Reference Detomi, Donadze, Morigi and Shumyatsky7].

Theorem 3.1 Let $G$ be a group such that $|x^{\gamma _k(G)}|\leq n$ for any $x\in G$. Then $\gamma _{k+1}(G)$ has finite $(k,n)$-bounded order.

We can now prove theorem 1.4.

Proof of theorem 1.4. Recall that $K$ is a subgroup of the finite group $G$ such that $\gamma _k(G)\leq K$ and $Pr(K,G)\geq \epsilon$. In view of [Reference Erfanian, Rezaei and Lescot10, theorem 3.7] observe that $Pr(\gamma _k(G),G)\geq \epsilon$. Therefore without loss of generality we can assume that $K=\gamma _k(G)$.

Proposition 1.2 tells us that there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$ and the order of $[T,B]$ are $\epsilon$-bounded. In particular, $|x^{B}|$ is $\epsilon$-bounded for every $x\in T$. Since $B$ has $\epsilon$-bounded index in $K$, we deduce that $|x^{\gamma _k(G)}|$ is $\epsilon$-bounded for every $x\in T$. Now theorem 3.1 implies that $\gamma _{k+1}(T)$ has $\epsilon$-bounded order. Set $R=C_T(\gamma _{k+1}(T))$. It follows that $R$ is as required.

Our next goal is a proof of theorem 1.5. As mentioned in the introduction, a group-word $w$ implies virtual nilpotency if every finitely generated metabelian group $G$ where $w$ is a law, that is $w(G)=1$, has a nilpotent subgroup of finite index. A theorem, due to Burns and Medvedev, states that for any word $w$ implying virtual nilpotency there exist integers $e$ and $c$ depending only on $w$ such that every finite group $G$, in which $w$ is a law, has a nilpotent of class at most $c$ normal subgroup $N$ with $G^{e}\leq N$ [Reference Burns and Medvedev4].

Proof of theorem 1.5. Recall that $w$ is a group-word implying virtual nilpotency while $K$ is a subgroup of a finite group $G$ such that $w(G)\leq K$ and $Pr(K,G)\geq \epsilon$. We need to show that there is an $(\epsilon,w)$-bounded integer $e$ and a $w$-bounded integer $c$ such that $G^{e}$ is nilpotent of class at most $c$.

As in the proof of theorem 1.4 without loss of generality we can assume that $K=w(G)$. Proposition 1.2 tells us that there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$ and the order of the commutator subgroup $[T,B]$ are $\epsilon$-bounded. According to remark 2.7 the subgroup $T$ can be chosen in such a way that $K\cap T\leq Z_3(T)$. In particular $w(T)\leq Z_3(T)$. Taking into account that the word $w$ implies virtual nilpotency, we deduce from the Burns–Medvedev theorem that there are $w$-bounded numbers $i$ and $c$ such that the subgroup generated by the $i$th powers of elements of $T$ is nilpotent of class at most $c$. Recall that the index of $T$ in $G$ is $\epsilon$-bounded. Hence there is an $\epsilon$-bounded integer $e$ such that every $e$th power in $G$ is an $i$th power of an element of $T$. The result follows.

If $[x^{i},y_1,\dots,y_j]$ is a law in a finite group $G$, then $\gamma _{j+1}(G)$ has $\{i,j\}$-bounded exponent (the case $j=1$ is a well-known result, due to Mann [Reference Mann24]; see [Reference Caldeira and Shumyatsky5, lemma 2.2] for the case $j\geq 2$). If the $j$-Engel word $[x,y,\dots,y]$, where $y$ is repeated $j$ times, is a law in a finite group $G$, then $G$ has a normal subgroup $N$ such that the exponent of $N$ is $j$-bounded while $G/N$ is nilpotent with $j$-bounded class [Reference Burns and Medvedev3]. Note that both words $[x^{i},y_1,\dots,y_j]$ and $[x,y,\dots,y]$ imply virtual nilpotency.

Therefore, in addition to theorem 1.5, we deduce

Theorem 3.2 Assume the hypotheses of theorem 1.5.

  1. If $w=[x^{n},y_1,\dots,y_k]$, then $G$ has a normal subgroup $T$ such that the index $[G:T]$ is $\epsilon$-bounded and the exponent of $\gamma _{k+4}(T)$ is $w$-bounded.

  2. There are $k$-bounded numbers $e_1$ and $c_1$ with the property that if $w$ is the $k$-Engel word, then $G$ has a normal subgroup $T$ such that the index $[G:T]$ is $\epsilon$-bounded and the exponent of $\gamma _{c_1}(T)$ divides $e_1$.

Proof. By [Reference Erfanian, Rezaei and Lescot10, theorem 3.7], without loss of generality we can assume that $K=w(G)$. Proposition 1.2 tells us that there is a normal subgroup $T\leq G$ and a subgroup $B\leq w(G)$ such that the indices $[G:T]$ and $[w(G):B]$ and the order of $[T,B]$ are $\epsilon$-bounded. Since $K$ is normal in $G$, according to remark 2.7 the subgroup $T$ can be chosen in such a way that $w(G)\cap T\leq Z_3(T)$. If $w=[x^{n},y_1,\dots,y_k]$, then $[x^{n},y_1,\dots,y_{k+3}]$ is a law in $T$, whence the exponent of $\gamma _{k+4}(T)$ is $w$-bounded. If $w$ is the $k$-Engel word, then the $(k+3)$-Engel word is a law in $T$ and the theorem follows from the Burns–Medvedev theorem [Reference Burns and Medvedev3].

4. Sylow subgroups

As usual, $O_p(G)$ denotes the maximal normal $p$-subgroup of a finite group $G$. For the reader's convenience we restate theorem 1.6:

Let $P$ be a Sylow $p$-subgroup of a finite group $G$ such that $Pr(P,G) \ge \epsilon$. Then $G$ has a class- $2$-nilpotent normal $p$-subgroup $L$ such that both the index $[P:L]$ and the order of the commutator subgroup $[L,L]$ are $\epsilon$-bounded.

Proof of Theorem 1.6. Proposition 1.2 tells us that there is a normal subgroup $T\leq G$ and a subgroup $B\leq P$ such that the indices $[G:T]$ and $[P:B]$ and the order of the commutator subgroup $[T,B]$ are $\epsilon$-bounded. In view of remark 2.6 the subgroup $N=\langle [T,B]^{G}\rangle$ has $\epsilon$-bounded order. Therefore $C=C_T(N)$ has $\epsilon$-bounded index in $G$. Set $B_0=B\cap C$ and note that $[C,B_0]\leq Z(C)$. It follows that $B_0\leq Z_2(C)$ and we conclude that $B_0\leq O_p(G)$. Let $L=\langle {B_0}^{G}\rangle$. As $B_0 \le L \le O_p(G)$, it is clear that $L$ is contained in $P$ as a subgroup of $\epsilon$-bounded index. Moreover $[L,L]\leq N$ and so the order of $[L,L]$ is $\epsilon$-bounded. Hence the result.

We will now prove theorem 1.7.

Proof of theorem 1.7. Recall that $G$ is a finite group such that $Pr(P,G) \ge \epsilon$ whenever $P$ is a Sylow subgroup. We wish to show that $G$ has a nilpotent normal subgroup $R$ of nilpotency class at most $2$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $\epsilon$-bounded.

For each prime $p\in \pi (G)$ choose a Sylow $p$-subgroup $S_p$ in $G$. Theorem 1.6 shows that $G$ has a normal $p$-subgroup $L_p$ of class at most $2$ such that both $[S_p:L_p]$ and $|[L_p,L_p]|$ are $\epsilon$-bounded. Since the bounds on $[S_p:L_p]$ and $|[L_p,L_p]|$ do not depend on $p$, it follows that there is an $\epsilon$-bounded constant $C$ such that $S_p=L_p$ and $[L_p,L_p]=1$ whenever $p\geq C$. Set $R=\prod _{p\in \pi (G)}L_p$. Then all Sylow subgroups of $G/R$ have $\epsilon$-bounded order and therefore the index of $R$ in $G$ is $\epsilon$-bounded. Moreover, $R$ is of class at most $2$ and $|[R,R]|$ is $\epsilon$-bounded, as required.

5. Coprime automorphisms and their fixed points

If $A$ is a group of automorphisms of a group $G$, we write $C_G(A)$ for the centralizer of $A$ in $G$. The symbol $A^{\#}$ stands for the set of nontrivial elements of the group $A$.

The next lemma is well-known (see e.g. [Reference Gorenstein11, theorem 6.2.2 (iv)]). In the sequel we use it without explicit references.

Lemma 5.1 Let $A$ be a group of automorphisms of a finite group $G$ such that $(|G|,|A|)=1$. Then $C_{G/N}(A)=NC_G(A)/N$ for any $A$-invariant normal subgroup $N$ of $G$.

Proof of theorem 1.8. Recall that $G$ is a finite group admitting a coprime automorphism $\phi$ of prime order $p$ such that $Pr(K,G)\geq \epsilon$, where $K=C_G(\phi )$. We need to show that $G$ has a nilpotent subgroup of $p$-bounded nilpotency class and $(\epsilon,p)$-bounded index.

By proposition 1.2 there is a normal subgroup $T\leq G$ and a subgroup $B\leq K$ such that the indices $[G:T]$ and $[K:B]$ and the order of the commutator subgroup $[T,B]$ are $\epsilon$-bounded. Let $T_0$ be the maximal $\phi$-invariant subgroup of $T$. Evidently, $T_0$ is normal and the index $[G:T_0]$ is $(\epsilon,p)$-bounded. Since $\langle [T_0,B]^{G}\rangle \leq \langle [T,B]^{G}\rangle$, remark 2.6 implies that $M=\langle [T_0,B]^{G}\rangle$ has $\epsilon$-bounded order. Moreover, $M$ is $\phi$-invariant. Set $D=C_G(M)\cap T_0$ and $\bar {D}=D/Z_2(D)$, and note that $D$ is $\phi$-invariant.

In a natural way $\phi$ induces an automorphism of $\bar {D}$ which we will denote by the same symbol $\phi$. We note that $C_{\bar {D}}(\phi )=C_D(\phi ) Z_2(D)/Z_2(D)$, so its order is $\epsilon$-bounded because $B\cap D\leq Z_2(D)$. The Khukhro theorem [Reference Khukhro21] now implies that $\bar {D}$ has a nilpotent subgroup of $p$-bounded class and $(\epsilon,p)$-bounded index. Since $\bar {D}=D/Z_2(D)$ and since the index of $D$ in $G$ is $(\epsilon,p)$-bounded, we deduce that $G$ has a nilpotent subgroup of $p$-bounded class and $(\epsilon,p)$-bounded index. The proof is complete.

A proof of the next lemma can be found in [Reference Guralnick and Shumyatsky14].

Lemma 5.2 If $A$ is a noncyclic elementary abelian $p$-group acting on a finite $p'$-group $G$ in such a way that $|C_G(a)|\leq m$ for each $a\in A^{\#}$, then the order of $G$ is at most $m^{p+1}$.

We will now prove theorem 1.9.

Proof of theorem 1.9. By hypotheses, $G$ is a finite group admitting an elementary abelian coprime group of automorphisms $A$ of order $p^{2}$ such that $Pr(C_G(\phi ),G)\geq \epsilon$ for each $\phi \in A^{\#}$. We need to show that $G$ has a nilpotent normal subgroup $R$ of nilpotency class at most $2$ such that both the index $[G:R]$ and the order of the commutator subgroup $[R,R]$ are $(\epsilon,p)$-bounded.

Let $A_1,\dots,A_{p+1}$ be the subgroups of order $p$ of $A$ and set $G_i=C_G(A_i)$ for $i=1,\dots,p+1$. According to proposition 1.2 for each $i=1,\dots,p+1$ there is a normal subgroup $T_i\leq G$ and a subgroup $B_i\leq G_i$ such that the indices $[G:T_i]$ and $[G_i:B_i]$ and the order of the commutator subgroup $[T_i,B_i]$ are $\epsilon$-bounded. We let $U_i$ denote the maximal $A$-invariant subgroup of $T_i$ so that each $U_i$ is a normal subgroup of $(\epsilon,p)$-bounded index. The intersection of all $U_i$ will be denoted by $U$. Further, we let $D_i$ denote the maximal $A$-invariant subgroup of $B_i$ so that each $D_i$ has $(\epsilon,p)$-bounded index in $G_i$. Note that a modification of remark 2.6 implies that $N_i=\langle [U_i,D_i]^{G}\rangle$ is $A$-invariant and has $\epsilon$-bounded order. It follows that the order of $N=\prod _iN_i$ is $(\epsilon,p)$-bounded. Let $V$ denote the minimal ($A$-invariant) normal subgroup of $G$ containing all $D_i$ for $i=1,\dots,p+1$. It is easy to see that $[U,V]\leq N$.

Obviously, $U$ has $(\epsilon,p)$-bounded index in $G$. Let us check that this also holds with respect to $V$. Let $\bar {G}=G/V$. Since $V$ contains $D_i$ for each $i=1,\dots,p+1$ and since $D_i$ has $(\epsilon,p)$-bounded index in $G_i$, we conclude that the image of $G_i$ in $\bar {G}$ has $(\epsilon,p)$-bounded order. Now lemma 5.2 tells us that the order of $\bar {G}$ is $(\epsilon,p)$-bounded and we conclude that indeed $V$ has $(\epsilon,p)$-bounded index in $G$. Also note that since $N$ has $(\epsilon,p)$-bounded order, $C_G(N)$ has $(\epsilon,p)$-bounded index in $G$. Let

\[ R=U\cap V\cap C_G(N). \]

Then $R$ is as required since the subgroups $U,V,C_G(N)$ have $(\epsilon,p)$-bounded index in $G$ while $[R,R]\leq N\leq C_G(R)$. The proof is complete.

Acknowledgments

The first author is a member of GNSAGA (Indam). The second author was supported by FAPDF and CNPq.

References

Acciarri, C. and Shumyatsky, P.. A stronger form of Neumann's BFC-theorem. Israel J. Math. 242 (2021), 269278. https://doi.org/10.1007/s11856-021-2133-1.CrossRefGoogle Scholar
Black, S.. Which words spell ‘almost nilpotent’? J. Algebra 221 (1999), 475496.CrossRefGoogle Scholar
Burns, R. G. and Medvedev, Y.. A note on Engel groups and local nilpotence. J. Aust. Math. Soc. 64 (1998), 92100.CrossRefGoogle Scholar
Burns, R. G. and Medvedev, Y.. Group laws implying virtual nilpotence. J. Aust. Math. Soc. 74 (2003), 295312.CrossRefGoogle Scholar
Caldeira, J. and Shumyatsky, P.. On verbal subgroups in residually finite groups. Bull. Aust. Math. Soc. 84 (2011), 159170.CrossRefGoogle Scholar
Detomi, E., Morigi, M. and Shumyatsky, P.. BFC-theorems for higher commutator subgroups. Q. J. Math. 70 (2019), 849858.CrossRefGoogle Scholar
Detomi, E., Donadze, G., Morigi, M. and Shumyatsky, P.. On finite-by-nilpotent groups. Glasgow Math. J. 63 (2021), 5458.CrossRefGoogle Scholar
Dierings, G. and Shumyatsky, P.. Groups with boundedly finite conjugacy classes of commutators. Q. J. Math. 69 (2018), 10471051.CrossRefGoogle Scholar
Eberhard, S.. Commuting probabilities of finite groups. Bull. London Math. Soc. 47 (2015), 796808.CrossRefGoogle Scholar
Erfanian, A., Rezaei, R. and Lescot, P.. On the relative commutativity degree of a subgroup of a finite group. Comm. Algebra 35 (2007), 41834197.CrossRefGoogle Scholar
Gorenstein, D.. Finite groups (New York: Chelsea Publishing Company, 1980).Google Scholar
Groves, J. R. J.. Varieties of soluble groups and a dichotomy of P. Hall. Bull. Austral. Math. Soc. 5 (1971), 391410.CrossRefGoogle Scholar
Gruenberg, K. W.. Two theorems on engel groups. Proc. Cambridge Philos. Soc. 49 (1953), 377380.CrossRefGoogle Scholar
Guralnick, R. M. and Shumyatsky, P.. Derived subgroups of fixed points. Israel J. Math. 126 (2001), 345362.CrossRefGoogle Scholar
Guralnick, R. M. and Robinson, G.. On the commuting probability in finite groups. J. Algebra 300 (2006), 509528.CrossRefGoogle Scholar
Guralnick, R. M. and Maroti, A.. Average dimension of fixed point spaces with applications. Adv. Math. 226 (2011), 298308.CrossRefGoogle Scholar
Gustafson, W. H.. What is the probability that two group elements commute? Amer. Math. Monthly 80 (1973), 10311034.CrossRefGoogle Scholar
Hall, M. J.. The theory of groups (New York: The Macmillan Co., 1959).Google Scholar
Higman, G.. Groups and rings having automorphisms without non-trivial fixed elements. J. London Math. Soc. 32 (1957), 321334.CrossRefGoogle Scholar
Huppert, B. and Blackburn, N.. Finite groups III (Berlin: Springer-Verlag, 1982).CrossRefGoogle Scholar
Khukhro, E. I.. Groups and Lie rings admitting an almost regular automorphism of prime order. Math. USSR-Sb. 71 (1992), 5163.CrossRefGoogle Scholar
Lescot, P.. Sur certains groupes finis, Rev. Math. Spéciales, Avril 1987, pp. 276–277.Google Scholar
Lescot, P.. Degré de commutativité et structure d'un groupe fini (1), Rev. Math. Spéciales, Avril 1988, pp. 276–279.Google Scholar
Mann, A.. The exponent of central factors and commutator groups. J. Group Theory 10 (2007), 435436.CrossRefGoogle Scholar
Mann, A.. Groups satisfying identities with high probability. Int. J. Algebra Comput. 28 (2018), 15751584.CrossRefGoogle Scholar
Nath, R. K. and Yadav, M. K.. Some results on relative commutativity degree. Rend. Circ. Mat. Palermo 64 (2015), 229239.CrossRefGoogle Scholar
Neumann, B. H.. Groups covered by permutable subsets. J. London Math. Soc. 29 (1954), 236248.CrossRefGoogle Scholar
Neumann, P. M. and Vaughan-Lee, M. R.. An essay on BFC groups. Proc. Lond. Math. Soc. 35 (1977), 213237.CrossRefGoogle Scholar
Neumann, P. M.. Two combinatorial problems in group theory. Bull. Lond. Math. Soc. 21 (1989), 456458.CrossRefGoogle Scholar
Robinson, D. J. S.. A course in the theory of groups, 2nd ed. Graduate Texts in Mathematics, 80. (New York: Springer-Verlag, 1996).CrossRefGoogle Scholar
Segal, D. and Shalev, A.. On groups with bounded conjugacy classes. Q. J. Math. Oxford 50 (1999), 505516.CrossRefGoogle Scholar
Shalev, A.. Probabilistically nilpotent groups. Proc. Amer. Math. Soc. 146 (2018), 15291536.CrossRefGoogle Scholar
Thompson, J.. Finite groups with fixed-point-free automorphisms of prime order. Proc. Nat. Acad. Sci. U.S.A. 45 (1959), 578581.CrossRefGoogle ScholarPubMed
Wiegold, J.. Groups with boundedly finite classes of conjugate elements. Proc. Roy. Soc. London Ser. A 238 (1957), 389401.Google Scholar