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A CHARACTERISATION OF SOLUBLE ${PST}$-GROUPS

Published online by Cambridge University Press:  15 March 2024

ZHIGANG WANG
Affiliation:
School of Mathematics and Statistics, Hainan University, Haikou, Hainan 570228, PR China e-mail: [email protected]
A-MING LIU
Affiliation:
School of Mathematics and Statistics, Hainan University, Haikou, Hainan 570228, PR China e-mail: [email protected]
VASILY G. SAFONOV
Affiliation:
Institute of Mathematics of the National Academy of Sciences of Belarus, Minsk 220072, Belarus and Department of Mechanics and Mathematics, Belarusian State University, Minsk 220030, Belarus e-mail: [email protected], [email protected]
ALEXANDER N. SKIBA*
Affiliation:
Department of Mathematics and Technologies of Programming, Francisk Skorina Gomel State University, Gomel 246019, Belarus
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Abstract

Let G be a finite group. A subgroup A of G is said to be S-permutable in G if A permutes with every Sylow subgroup P of G, that is, $AP=PA$. Let $A_{sG}$ be the subgroup of A generated by all S-permutable subgroups of G contained in A and $A^{sG}$ be the intersection of all S-permutable subgroups of G containing A. We prove that if G is a soluble group, then S-permutability is a transitive relation in G if and only if the nilpotent residual $G^{\mathfrak {N}}$ of G avoids the pair $(A^{s G}, A_{sG})$, that is, $G^{\mathfrak {N}}\cap A^{sG}= G^{\mathfrak {N}}\cap A_{sG}$ for every subnormal subgroup A of G.

Type
Research Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Australian Mathematical Publishing Association Inc.

1. Introduction

Throughout this paper, all groups are finite and G always denotes a finite group.

Let $K\leq H$ and A be subgroups of G. Then we say that A avoids the pair $(H, K)$ if $A\cap H =A\cap K$ .

A subgroup H of G is said to be Sylow permutable or S-permutable [Reference Ballester-Bolinches, Beidleman and Heineken2, Reference Ballester-Bolinches, Esteban-Romero and Asaad3] in G if H permutes with every Sylow subgroup P of G, that is, $HP=PH$ .

The S-permutable subgroups possess a series of interesting properties and they are closely related to subnormal subgroups. For instance, if $ H$ is an S-permutable subgroup of G, then H is subnormal in G (Kegel [Reference Kegel10]), the normaliser $N_{G}(H)$ of H is also S-permutable in G (Schmid [Reference Schmid12]) and the quotient $H/H_{G}$ is nilpotent (Deskins [Reference Deskins6]).

Note also that the S-permutable subgroups of G form a sublattice of the lattice of all subnormal subgroups of G (Kegel [Reference Kegel10]) and this important result allows us to associate with each subgroup A of G two S-permutable subgroups of G: the S-core $A_{sG}$ of A in G [Reference Skiba13], that is, the subgroup of A generated by all S-permutable subgroups of G contained in A and the S-permutable closure $A^{sG}$ of A in G [Reference Guo and Skiba8], that is, the intersection of all S-permutable subgroups of G containing A.

The subgroups $A_{sG}$ and $A^{sG}$ have found numerous applications in the study of the structure of nonsimple groups (see, in particular, [Reference Guo and Skiba8, Reference Miao11, Reference Skiba13, Reference Wei, Lv, Dai, Zhang and Yang14]), and in this paper, we consider the use of such subgroups in the theory of ${PST}$ -groups.

Recall that G is a ${PST}$ -group [Reference Ballester-Bolinches, Beidleman and Heineken2, Reference Ballester-Bolinches, Esteban-Romero and Asaad3] if S-permutability is a transitive relation in G, that is, if K is an S-permutable subgroup of H and H is an S-permutable subgroup of G, then K is S-permutable in G. The description of soluble ${PST}$ -groups was first obtained by Agrawal [Reference Agrawal1].

Theorem 1.1 (Agrawal [Reference Agrawal1]).

Let $D=G^{\mathfrak {N}}$ be the nilpotent residual of a soluble group G, that is, the intersection of all normal subgroups N of G with nilpotent $G/N$ . Then G is a ${PST}$ -group if and only if D is an abelian Hall subgroup of G of odd order and every element of $ G$ induces a power automorphism in D.

There are many other interesting characterisations of soluble ${PST}$ -groups (see, for example, [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Ch. 2]). In particular, a soluble group G is a ${PST}$ -group if and only if every chief factor of G between $A^{G}$ and $A_{G}$ is central in G for every subgroup A of G such that $A^{G}/A_{G}$ is nilpotent [Reference Chi and Skiba5], and a soluble group G is a ${PST}$ -group if and only if for every maximal subgroup V of every Sylow subgroup of G, there is a ${PST}$ -subgroup T of G such that $G=VT$ [Reference Guo, Guo, Safonova and Skiba7].

In this paper, we prove the following result.

Theorem 1.2. Let $D=G^{\mathfrak {N}}$ be the nilpotent residual of a soluble group G. Then G is a ${PST}$ -group if and only if D avoids the pair $(A^{sG}, A_{sG})$ for every subnormal subgroup A of G.

2. Preliminaries

Lemma 2.1. If D avoids the pair $(A^{sG}, A_{sG})$ and for a minimal normal subgroup R of G we have either $R \leq D$ or $R \leq A$ , then $DR/R$ avoids the pair $((AR/R)^{s(G/R)}, (AR/R)_{s(G/R)})$ .

Proof. First assume that $R \leq D$ . Then

$$ \begin{align*} (DR/R)\cap (AR/R)^{s(G/R)}= (D/R)\cap (A^{sG}R/R) & =(D\cap A^{sG}R)/R \\ & =R(D\cap A^{sG})/R \leq R(D\cap A_{sG})/R. \end{align*} $$

However,

$$ \begin{align*}R(D\cap A_{sG})/R\leq (D\cap (AR)_{sG})/R = (D/R)\cap (AR)_{sG}/R =(DR/R)\cap (AR/R)_{s(G/R)}.\end{align*} $$

Therefore, $(DR/R)\cap (AR/R)^{s(G/R)}\leq (DR/R)\cap (AR/R)_{s(G/R)} $ and hence

$$ \begin{align*}(DR/R)\cap (AR/R)^{s(G/R)} =(DR/R)\cap (AR/R)_{s(G/R)}, \end{align*} $$

so $DR/R$ avoids the pair $((AR/R)^{s(G/R)}, (AR/R)_{s(G/R)})$ .

Now assume that $R \leq A$ . Then

$$ \begin{align*} (DR/R)\cap (AR/R)^{s(G/R)} & = (DR/R)\cap (A^{sG}/R)=(DR\cap A^{sG})/R=R(D\cap A^{sG})/R \\ & \leq R(D\cap A_{sG})/R \\ & \leq (DR/R) \cap (A_{sG}/R)= (DR/R)\cap (A/R)_{s(G/R)}. \end{align*} $$

Hence, $DR/R$ avoids $((AR/R)^{s(G/R)},(AR/R)_{s(G/R)})$ .

The following lemma is a corollary of [Reference Guo and Skiba8, Lemmas 2.4 and 2.5].

Lemma 2.2. If $A\leq E\leq G$ , then $A_{sG}\leq A_{sE}\leq A\leq A^{sE}\leq A^{sG}$ .

The following useful fact is obtained from [Reference Ballester-Bolinches and Ezquerro4, Proposition 2.2.8].

Lemma 2.3. Let N and E be subgroups of G, where N is normal in G. Then:

  1. (1) $(G/N)^{\frak {N}}=G^{\frak {N}}N/N$ ;

  2. (2) $E^{\frak {N}}\leq G^{\frak {N}}$ ; and

  3. (3) if $G=NE$ , then $E^{\frak {N}}N=G^{\frak {N}}N$ .

Lemma 2.4. If the nilpotent residual $D=G^{\mathfrak {N}}$ of G avoids the pair $(A^{sG}, A_{sG})$ and $A\leq E\leq G$ , then $E^{\mathfrak {N}}$ avoids the pair $(A^{sE}, A_{sE})$ .

Proof. We have $A_{sG}\leq A_{sE}\leq A\leq A^{sE}\leq A^{G}$ by Lemma 2.2, and so from $A^{sG}\cap D=A_{sG}\cap D$ and Lemma 2.3(2), it follows that $E^{\mathfrak {N}}\cap A^{sG}\leq E^{\mathfrak {N}}\cap A_{sG}$ , where $E^{\mathfrak {N}}\cap A^{sE}\leq E^{\mathfrak {N}}\cap A^{sG}$ and $ E^{\mathfrak {N}}\cap A_{sG}\leq E^{\mathfrak {N_{\sigma }}}\cap A_{sE}$ .

Consequently, $E^{\mathfrak {N}}\cap A^{sE}\leq E^{\mathfrak {N}}\cap A_{sE}\leq E^{\mathfrak {N}}\cap A^{sE}$ and $E^{\mathfrak {N}}\cap A^{sE}= E^{\mathfrak {N}}\cap A_{sE}$ . Hence, $E^{\mathfrak {N}}$ avoids the pair $(A^{sEG}, A_{sE})$ . The lemma is proved.

A group G is called $\pi $ -closed if G has a normal Hall $\pi $ -subgroup.

Lemma 2.5. Let $K\leq H $ be normal subgroups of G, where $H/K$ is $\pi $ -closed. If either $K\leq \Phi (G)$ or $K\leq Z_{\infty }(H)$ , then H is $\pi $ -closed.

Proof. Let $V/K $ be the normal Hall $\pi $ -subgroup of $H/K$ . Let D be a Hall $\pi '$ -subgroup of K. Then D is a normal Hall $\pi '$ -subgroup of V since K is nilpotent, so V has a Hall $\pi $ -subgroup, E say, by the Schur–Zassenhaus theorem. It is clear that V is $\pi '$ -soluble, so any two Hall $\pi $ -subgroups of V are conjugated in V by the Hall–Chunikhin theorem on $\pi $ -soluble groups.

Assume that $K\leq \Phi (G)$ . By a generalised Frattini argument, $G=VN_{G}(E)=DEN_{G}(E)=DN_{G}(E)=N_{G}(E)$ since $D\leq K\leq \Phi (G)$ . Thus, E is normal in H, that is, H is $\pi $ -closed since E is a Hall $\pi $ -subgroup of H.

Finally, assume that $K\leq Z_{\infty }(H)$ and then $D\leq Z_{\infty }(V)$ , so $V=D\rtimes E=D\times E$ . Hence, E is characteristic in V and so normal in H. Thus, H is $\pi $ -closed. The lemma is proved.

Lemma 2.6. Let $D=G^{\frak {N}}$ be the nilpotent residual of G and p a prime such that $(p-1, |G|)=1$ . If D is nilpotent and every subgroup of D is normal in G, then $(p, |D|)=1$ . Hence, the smallest prime in $\pi (G)$ belongs to $\pi (|G:D|)$ . In particular, $|D|$ is odd and so D is abelian.

Proof. Assume that p divides $|D|$ . Then D has a maximal subgroup M such that $|D:M|=p$ and M is normal in G. It follows that $C_{G}(D/M)=G$ , that is, $D/M\leq Z(G/M)$ since $(p-1, |G|)=1$ . However, $G/D$ is nilpotent. Therefore, $G/M$ is nilpotent by Lemma 2.5 and hence $D\leq M < D$ , which is a contradiction. Therefore, the smallest prime in $\pi (G)$ belongs to $\pi (|G:D|)$ . In particular, $|D|$ is odd and so D is abelian since D is a Dedekind group by hypothesis. The lemma is proved.

Definition 2.7. A subgroup D of G is a special subgroup of G if D is a normal Hall subgroup of G and every element of G induces a power automorphism in D.

Lemma 2.8. If D is a special subgroup of G and $N \trianglelefteq G$ , then $DN/N$ is a special subgroup of $G/N$ .

Proof. It is clear that $DN/N$ is a normal Hall subgroup of $G/N$ and if $A/N\leq DN/N$ , then $A=N(A\cap D)$ , where $A\cap D$ is normal in G, so $A/N$ is normal in $G/N$ , that is, every element of $G/N$ induces a power automorphism in $DN/N$ . The lemma is proved.

Lemma 2.9 [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Theorem 1.2.17].

If A is a nilpotent S-permutable subgroup of G and V is a Sylow subgroup of A, then V is S-permutable in G.

Lemma 2.10. If the nilpotent residual $D=G^{\mathfrak {N}}$ of G is a special subgroup of G and A is an S-permutable subgroup of G, then D avoids the pair $(A^{sG}, A_{sG})$ .

Proof. Since $A_{G}\leq A_{sG}\leq A\leq A^{sG}\leq A^{G}$ by Lemma 2.2, it is enough to show that D avoids the pair $(A^{G}, A_{G})$ . Assume this is false and let G be a counterexample of minimal order.

First we prove that $A\cap D=1$ . Indeed, assume that $N:=A\cap D\ne 1$ . Then $N\leq A_{G}$ and $D/N=(G/N)^{\mathfrak {N}}$ is a special subgroup of $G/N$ by Lemma 2.8, and $A/N$ is an S-permutable subgroup of $G/N$ by [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Lemma 1.2.7]. Therefore, $(G/N)^{\mathfrak {N}}$ avoids the pair $ ((A/N)^{G/N}, (A/N)_{G/N})$ by the choice of G, that is,

$$ \begin{align*}(G/N)^{\mathfrak{N}}\cap (A/N)^{G/N}= (G/N)^{\mathfrak{N}}\cap (A/N)_{G/N}.\end{align*} $$

However, $(A/N)^{G/N}=A^{G}/N$ and $(A/N)_{G/N}=A_{G}/N$ , so

$$ \begin{align*}(G/N)^{\mathfrak{N}}\cap (A/N)^{G/N}=(D/N)\cap (A^{G}/N)=(D\cap A^{G})/N\end{align*} $$

and

$$ \begin{align*}(G/N)^{\mathfrak{N}}\cap (A/N)_{G/N}=(D/N)\cap (A_{G}/N)=(D\cap A_{G})/N.\end{align*} $$

Consequently, $D\cap A^{G}=D\cap A_{G}$ . Hence, D avoids the pair $(A^{G}, A_{G})$ , which is a contradiction.

Therefore, $A\cap D=1$ , so $AD/D\simeq A= P_{1}\times \cdots \times P_{t}$ , where $P_{i}$ is the Sylow $p_{i}$ -subgroup of A for all i. Then $P_{i}$ is S-permutable in G by Lemma 2.9 and so $D\leq N_{G}(P_{i})$ for all i by [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Lemma 1.2.16]. Therefore, $D\leq N_{G}(A)$ .

Let $\pi =\pi (D)$ . Then G is $\pi $ -soluble since every subgroup of D is normal in G by hypothesis. Moreover, D has a complement M in G since D is a Hall $\pi $ -subgroup of G and for some $x\in G$ , we have $A\leq M^{x}$ by the Chunikhin–Hall theorem [Reference Huppert9, VI, Hauptsatz 1.7]. Finally, $D\leq N_{G}(A)$ and hence $A^{G}=A^{DM^{x}}=A^{M^{x}}\leq M_{G}\leq M$ , so $A^{G}\cap D=1$ . Therefore, D avoids $(A^{G}, A_{G})=(A^{G}, 1)$ , contrary to the choice of G. The lemma is proved.

3. Proof of Theorem 1.2

First suppose that D avoids the pair $(A^{sG}, A_{sG})$ for every subnormal subgroup A of G. We show that, in this case, G is a ${PST}$ -group. Assume this is false and let G be a counterexample of minimal order. Then $D\ne 1$ since $G/D$ is nilpotent and so $G/D$ is a ${PST}$ -group.

Claim 1. If R is a minimal normal subgroup of G, then $G/R$ is a ${PST}$ -group.

In view of the choice of G, it is enough to show that the hypothesis holds for $G/R$ . First note that $DR/R=(G/R)^{\mathfrak {N}}$ by Lemma 2.3 and if $A/R$ is a subnormal subgroup of $G/R$ , then A is subnormal in G, so D avoids the pair $(A^{sG}, A_{sG})$ by hypothesis. Therefore, $DR/R$ avoids the pair $((A/R)^{s(G/R)}, (A/R)_{s(G/R)})$ by Lemma 2.1. This proves Claim 1.

Claim 2. If E is a proper subnormal subgroup of G, then E is a ${PST}$ -group.

Every subnormal subgroup A of E is subnormal in G, so D avoids the pair $(A^{sG}, A_{sG})$ by hypothesis. However, then $E^{\mathfrak {N}}$ avoids the pair $(A^{sE}, A_{sE})$ by Lemma 2.4. Hence, the hypothesis holds for E, so Claim 2 holds by the choice of G.

Claim 3. D is nilpotent and every subgroup of D is S-permutable in G. Hence, every chief factor of G below D is cyclic.

First we show that if $L\leq D$ , where L is a minimal normal subgroup of G, then L is cyclic. Since G is soluble, $L\leq G_{p}$ for some Sylow subgroup $G_{p}$ of G and then some maximal subgroup V of L is normal in $G_{p}$ and V is subnormal in G. Assume that V is not S-permutable in G. Then $V\ne 1$ and $V^{sG}=L$ , so $V^{sG}\cap D=L=V_{sG}\cap D < V< L,$ which is a contradiction. Hence, V is S-permutable in G, so $G=G_{p}O^{p}(G)\leq N_{G}(V)$ by [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Lemma 1.2.16]. Therefore, $V=1$ , so $|L|=p$ .

Now we show that D is nilpotent. Assume that this is false and let R be a minimal normal subgroup of G. Then $G/R$ is a ${PST}$ -group by Claim 1.

Note also that $(G/R)^{\frak {N}}=RD/R \simeq D/(D\cap R)$ by Lemma 2.3, where $(G/R)^{\frak {N}}$ is abelian by Theorem 1.1, so $R\leq D$ and if N is a minimal normal subgroup of G, then $N=R$ since otherwise $D\simeq D/1=D/(N\cap R)$ is abelian. Moreover, $|R|=p$ for some prime p and $R\nleq \Phi (G)$ by Lemma 2.5, so for some maximal subgroup M of G, we have $G=R\rtimes M$ and $C_{G}(R)\cap M$ is a normal subgroup of G, so $C_{G}(R)\cap M=1$ . Therefore, $C_{G}(R)=R(C_{G}(R)\cap M)=R$ and then $G/R=G/C_{G}(R)$ is cyclic. Hence, $R=D$ is nilpotent. This contradiction shows that D is nilpotent. So, for every subgroup A of D,

$$ \begin{align*} A^{sG}=D\cap A^{sG}=D\cap A_{sG}=A_{sG}. \end{align*} $$

Therefore, every subgroup of D is S-permutable in G.

By Theorem 1.1 and Claim 1, every chief factor of G between R and D is cyclic, so every chief factor of G below D is cyclic by the Jordan–Hölder theorem for the chief series. Hence, Claim 3 holds.

Claim 4. D is a Hall subgroup of G.

Suppose that this is false and let P be a Sylow p-subgroup of D such that ${1 < P < G_{p}}$ , where $G_{p}\in \text {Syl}_{p}(G)$ .

(a) $D=P$ is a minimal normal subgroup of G and $|D|=p$ . Hence, $D\leq Z(G_{p})$ and $G_{p}$ is normal in G.

Let R be a minimal normal subgroup of G contained in D. Then R is a q-group for some prime q and $D/R=(G/R)^{\mathfrak {N}}$ is a Hall subgroup of $G/R$ by Claim 1 and Theorem 1.1.

Suppose that $PR/R \ne 1$ . Then $PR/R \in \text {Syl}_{p}(G/R)$ . If $q\ne p$ , then $P \in \text {Syl}_{p}(G)$ . This contradicts the fact that $P < G_{p}$ . Hence, $q=p$ , so $R\leq P$ and therefore, $P/R \in \text {Syl}_{p}(G/R)$ and again $P \in \text {Syl}_{p}(G)$ . This contradiction shows that $PR/R=1$ , which implies that $R=P$ is the unique minimal normal subgroup of G contained in D. Since D is nilpotent, a $p'$ -complement E of D is characteristic in D and so it is normal in G. Hence, $E=1$ , which implies that $R=D=P$ . Claim 3 implies that $|D|=p$ , so $D\leq Z(G_{p})$ . Finally, since $G/D$ is nilpotent and $D \leq G_{p}$ , $G_{p}$ is normal in G.

(b) $D\nleq \Phi (G)$ . Hence, $G=D\rtimes M$ for some maximal subgroup M of G and $C_{G}(D)=D\times (C_{G}(D)\cap M$ ).

This follows from part (a) since G is not nilpotent.

(c) If G has a minimal normal subgroup $L\ne D$ , then $G_{p}=D\times L$ . Hence, $O_{p'}(G)=1$ .

Indeed, $DL/L\simeq D$ is a Hall subgroup of $G/L$ by Theorem 1.1 and Claim 1. Hence, $G_{p}L/L=DL/L$ , so $G_{p}=D\times (L\cap G_{p})=D\times L$ since $G_{p}$ is normal in G by part (a). Thus, $O_{p'}(G)=1$ .

(d) $G_{p}\cap M\ne 1$ is normal in G.

Observe that $V\kern1.3pt{:=}\kern1.3pt G_{p}\cap M$ is normal in M by part (a). Also from $G_{p}\kern1.3pt{=}\kern1.3pt G_{p}\kern1.3pt{\cap}\kern1.3pt D\rtimes M= D(G_{p}\cap M)$ , where $D\leq Z(G_{p})$ by part (a), it follows that V is normal $G_{p}$ . Therefore, V is normal in G and $V\ne 1$ since $D < G_{p}$ .

(e) If $L\leq G_{p}\cap M$ , where L is a minimal normal subgroup of G, then $L= G_{p}\cap M$ and so $G_{p}=D\times L$ is abelian.

This follows from parts (c) and (d).

(f) Every normal subgroup Z of G contained in $G_{p}$ with $1\ne Z\ne G_{p}$ is G-isomorphic to either L or D. In particular, Z is a minimal normal subgroup of G and either $Z\in \{D, L\}$ or $D\simeq _{G}Z\simeq _{G}L$ , and so $C_{G}(D)=C_{G}(Z)=C_{G}(L)$ .

Assume that $D\ne Z\ne L$ . If $Z\cap L\ne 1$ , then $L\leq Z$ and so $Z=L(Z\cap D)=L$ since $1\ne Z\ne G_{p}=LD,$ which is a contradiction. Hence, $Z\cap L=1$ and $Z\cap D=1$ . Therefore, $G_{p}=D\times Z =D\times L$ and so the G-isomorphisms ${L\kern1.3pt{\simeq}\kern1.3pt LD/D\kern1.3pt{=}\kern1.3pt G_{p}/D \kern1.3pt{=}\kern1.3pt DZ/D\kern1.3pt{\simeq}\kern1.3pt Z }$ and $D\simeq DL/L= G_{p}/D = LZ/L \simeq Z $ yield $D\simeq _{G}Z\simeq _{G}L$ . In particular, Z is a minimal normal subgroup of G and $C_{G}(D)=C_{G}(Z)=C_{G}(L)$ .

(g) If $N=\langle ab \rangle $ , where $D=\langle a \rangle $ and b is an element of order p in L, then $|N|=p$ and $N\cap D=N\cap L=1.$

Since $G_{p}=D\times L$ is abelian by part (e) and $|D|=p$ by part (a), $|ab|=|N|=p$ . Hence, $N\cap D=N\cap L=1$ since $a\not \in L$ and $b\not \in D$ .

(h) N is a minimal normal subgroup of G.

First we show that N is normal in G. In view of [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Lemma 1.2.16] and part (e), it is enough to show that $N=N^{sG}$ is S-permutable in G. Assume that $N < N^{sG}$ . Then $|N^{sG}|> p$ . Since $G_{p}=DL$ by part (f) and $|D|=p$ by part (a),

$$ \begin{align*}|G_{p}:L|=p=|N^{sG}L/L|=|N^{sG}/(N^{sG}\cap L)|,\end{align*} $$

so $N^{sG}\cap L\ne 1$ . However, $N^{sG}\cap L$ is S-permutable in G by [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Theorem 1.2.19] and so $N^{sG}\cap L$ is normal in G by [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Lemma 1.2.16] and part (e). Hence, $L\leq N^{sG}$ by the minimality of L. Then $N^{sG} = N^{sG}\cap G_{p}=L(N^{sG}\cap D).$ However, N is subnormal in G and so $N^{sG}\cap D=N_{sG}\cap D=1$ . Hence, $N^{sG}=L$ and then $N\cap L\ne 1$ , in contrast to part (g). Hence, $N = N^{sG}$ and so N is normal in G. Therefore, N is a minimal normal subgroup of G since $|N|=p$ . This proves part (h).

(i) The final contradiction to prove Claim 4.

In view of parts (f), (g) and (h), $C_{G}(D)=C_{G}(N)=C_{G}(L)$ . However, $C_{G}(L)=G$ by part (e) since $G/D\simeq M$ is nilpotent and $L\leq M$ . Therefore, $D\leq Z(G)$ and so G is nilpotent. This contradiction proves Claim 4.

Claim 5. Every subgroup A of D is normal in G. Hence, every element of $ G$ induces a power automorphism in D.

Since D is nilpotent by Claim 3, it is enough to consider the case when A is a p-group for some prime p. Moreover, A is S-permutable in G by Claim 3 and the Sylow p-subgroup $D_{p}$ of D is a Sylow p-subgroup of G by Claim 4. Therefore, ${G=D_{p}O^{p}(G)=DO^{p}(G)\leq N_{G}(A)}$ by [Reference Ballester-Bolinches, Esteban-Romero and Asaad3, Lemma 1.2.16]. This proves Claim 5.

Claim 6. D is an abelian group of odd order.

This follows from Lemma 2.6 and Claim 5.

Claim 7. The final contradiction.

From Claims 36, it follows that G is a ${PST}$ -group by Theorem 1.1, in contrast to the choice of G. Hence, there is no minimal counterexample and G is a ${PST}$ -group.

Finally, given that G is a ${PST}$ -group, we show that D avoids the pair $(A^{sG}, A_{sG})$ for every subnormal subgroup A of G. There is a series $A=A_{0} \trianglelefteq A_{1} \trianglelefteq \cdots \trianglelefteq A_{n}=G$ , so A is S-permutable in G since G is a ${PST}$ -group. However, $D=G^{\mathfrak {N}}$ is a special subgroup of G by Theorem 1.1 and so D avoids the pair $(A^{sG}, A_{sG})$ by Lemma 2.10.

The theorem is proved.

Acknowledgement

The authors are deeply grateful for the helpful suggestions of the referee.

Footnotes

Research of the first and second authors was supported by the National Natural Science Foundation of China (Grant Nos. 12171126, 12101165). Research of the third and fourth authors was supported by the Ministry of Education of the Republic of Belarus (Grant Nos. 20211328, 20211778).

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