1. Introduction
Glauberman proved that if $n$
is a positive integer, $p$
is a prime and $G\leq \mbox {GL}(n,\,p)$
is a $p'$
-group which is nilpotent of class 2, then $|G| < |V|$
in [Reference Glauberman4, Proposition 1].
The goal of this paper is to generalize this result to an arbitrary linear group. For a finite group $G$
, we define $G^{c}=[G,\,G,\,G]=[G',\, G]$
; i.e., $G^{c}$
is the intersection of all normal subgroups of $G$
whose quotient group is nilpotent of class 2, so that $G/G^{c}$
is the (maximal) class 2 quotient of $G$
. In [Reference Keller and Yang6], Keller and the author generalized the above-mentioned result of Glauberman to solvable linear groups. It was conjectured in the same paper that the main result of that paper remains true for arbitrary finite groups in place of solvable groups. In this short note, we settle this conjecture, and our main results are as follows.
Theorem 1.1 Let a finite group $G$
act faithfully on a finite group $V$
. Then any one of the following conditions guarantees that
(1) $V$
is a $p$-group and $O_p(G)=1$;(2) $V$
is a completely reducible $G$-module, possibly of mixed characteristic.
Of course, when $G$
is nilpotent of class 2, this is just Glauberman's result.
We note that Theorem 1.1 can also be viewed as a strengthening of a result by Aschbacher and Guralnick, see [Reference Aschbacher and Guralnick1, Theorem 1]. They proved that the order of the abelian quotient $|G/G'|$
of $G$
, i.e., the class 1 quotient of $G$
, is strictly bounded above by $|V|$
, where $G$
is a finite faithful linear group on the finite module $V$
such that $O_p(G)=1$
for the characteristic $p$
of $V$
. Our result shows that even the class 2 quotient of $G$
is strictly bounded above by $|V|$
. We point out that the main result in [Reference Aschbacher and Guralnick1] has been generalized in a different direction in [Reference Keller and Yang5, Reference Keller and Yang7], where the upper bound $|V|$
is replaced by the largest orbit size. We shall also point out that our result also generalizes a result of Flavell [Reference Flavell3, Theroem A (i)], since we do not need coprimeness here.
2. Preliminary results
In this section, we state a few lemmas and propositions.
The following lemma is elementary.
Lemma 2.1 Let $G$
be a finite group and $N\unlhd G$
. Then
and
Lemma 2.2 Let $G$
be a finite group and let $N$
be a normal subgroup of $G$
such that $G/N$
is nilpotent. Let $p$
be a given prime and $N=S_1\times \cdots \times S_t$
be a direct product of isomorphic non-abelian simple groups $S_i$
. Assume that $S_i$
are all normal in $G$
and that $C_G(N)=1$
. Then there exists an abelian $p'$
-subgroup $A$
of $G$
such that $2^{t} |G/N| \leq |A|$
.
Proof. This is [Reference Qian and Yang8, Lemma 2.2].
Lemma 2.3 Let $N\trianglelefteq G$
. Assume that $H/N\leq G/N$
and $|(G/N):(G/N)^{c}| \leq |(H/N):(H/N)^{c}|$
. Then $|G:G^{c}| \leq |H:H^{c}|$
.
Proof. $|G:G^{c}| \leq |G:G^{c}||G^{c}\cap N|/|H^{c} \cap N|$
$= |G:G^{c} N||N:H^{c} \cap N| \leq |H:H^{c} N|| N:H^{c} \cap N|=|H:H^{c}|$
.
Lemma 2.4 Let $G$
be a finite solvable group. Then $G$
has a nilpotent subgroup $H$
such that $|G/G^{c}| \leq |H/H^{c}|$
.
Proof. This follows from the first half of the proof of [Reference Keller and Yang6, Theorem 2.3], where it reduces $G$
to be nilpotent. In fact, the proof shows that for any finite solvable group $G$
, we have $|G:G^{c}| \leq |F:F^{c}|$
where $F$
is the Fitting subgroup of $G$
.
Proposition 2.5 Let $G$
be a finite group with $O_p(G)=1$
for some prime $p$
. Then $G$
has a solvable subgroup $H$
with $O_p(H)=1$
such that $|G:G^{c}| \leq |H:H^{c}|$
.
Proof. We may assume $G$
is non-solvable, and we work by induction on $|G|$
. Let $E$
be a minimal normal subgroup of $G$
and write $D/E=O_p(G/E)$
. Assume that $G/D$
is non-solvable. By induction, $G/D$
has a solvable subgroup $B/D$
with $O_p(B/D)=1$
such that $|(G/D):(G/D)^{c}| \leq |(B/D):(B/D)^{c}|$
. By Lemma 2.3, we have
Since $O_p(D)\leq O_p(G)=1$
and $O_p(B/D)=1$
, we have $O_p(B)=1$
. Suppose that $B$
is solvable. Then $B$
meets the requirements. Suppose that $B$
is non-solvable. By induction, $B$
has a solvable subgroup $H$
with $O_p(H)=1$
such that $|B:B^{c}| \leq |H:H^{c}|$
. Then
so $H$
meets the requirements. Hence, we may assume that $G/D$
and $G/E$
are solvable for all minimal normal subgroups $E$
of $G$
.
Since $G$
is non-solvable, it forces that $E$
is non-solvable and is the unique minimal normal subgroup of $G$
. In particular, $C_G(E)=1$
. By Lemma 2.4, $G/E$
has a nilpotent subgroup $U/E$
such that
Observe that $O_p(U)\leq C_G(E)=1$
. Suppose that $U< G$
, applying the inductive hypothesis to $U$
, we get the required result. Hence, we may assume that $G/E$
is nilpotent.
Write $E=S_1\times \cdots \times S_t$
, where $S_1,\, \ldots ,\, S_t$
are isomorphic non-abelian simple groups. Let us investigate $D={\bigcap} _{i=1}^{t} N_G(S_i)$
. Since all $S_i$
are normal subgroups of $D$
, by Lemma 2.2 there exists an abelian $p'$
-subgroup $H$
of $D$
such that $2^{t}|D/E| \leq |H|$
. Observe that $G$
acts on $\{S_1,\, \ldots ,\, S_t\}$
with the kernel $D$
, it follows that $G/D$
is a nilpotent permutation group of degree $t$
. As is well known (see, for example, [Reference Dixon2]), we have that $|G/D|\leq 2^{t-1}$
. Now
so $H$
meets the requirements.
3. The main result
We now prove the main result of this paper, Theorem 1.1.
Proof. (1) Set $K=G\ltimes V$
. It is clear that $F(K)$
is nilpotent, so we can write $F(K) = P \times Q$
, where $P$
is a $p$
-group and $Q$
is a $p'$
-group. Note that both $P$
and $Q$
are normal in $K$
, which implies that $PV/V$
is a normal $p$
-subgroup of $K/V \cong G$
and $[Q,\,V] \leq Q \cap V = 1$
. Now the assumptions that $O_p(G) = 1$
and ${{\mathbf {C}}}_G(V) = 1$
guarantee that $P \leq V$
and $Q = 1$
, so $F(K) = P \leq V$
. But the converse containment is clear, so $\varPhi (K) \leq F(K) = V$
. If $\varPhi (K) = V$
, then $K = GV = G \varPhi (K)$
, which forces $K = G$
and hence $V = 1$
, a trivial case. Thus, we have $F(K)=V$
and $\varPhi (K)< V$
.
Set
Observe that $\overline {G}$
also acts faithfully on $\overline {V}$
. We note this assertion is equivalent to saying that $G$
acts faithfully on $\overline {V}$
. Let $C = {{\mathbf {C}}}_G(\overline {V})$
, and take $A$
to be a $p'$
-subgroup of $C$
. Then $[V,\,A] \leq \varPhi (K)$
. Since $A$
acts coprimely on $V$
, we have $V = [V,\, A] {{\mathbf {C}}}_V(A) = \varPhi (K) {{\mathbf {C}}}_V(A)$
and thus $K = GV = \varPhi (K) G {{\mathbf {C}}}_V(A)$
. This forces $GV = G{{\mathbf {C}}}_V(A)$
and hence $V = {{\mathbf {C}}}_V(A)$
. Note that we are assuming that ${{\mathbf {C}}}_G(V) = 1$
, so $A = 1$
, which means that $C$
is a $p$
-group. But $O_p(G) = 1$
by hypotheses, so $C = 1$
, as required.
Assume that $\varPhi (K)>1$
. By induction,
and we are done. Therefore, we may assume that $\varPhi (K)=1$
. By Proposition 2.5, we may assume that the group $G$
is solvable. Since $F(K) = V$
, $V$
is a faithful and completely reducible $G$
-module over a field of characteristic $p$
by Gaschütz's theorem. Now the result follows by [Reference Keller and Yang6, Theorem 1.1].
(2) Suppose that $V$
is a finite, faithful and completely reducible $G$
-module. We work by induction on $|G|+|V|$
. Assume that $V=V_1\oplus V_2$
, where $V_1,\, V_2$
are non-trivial $G$
-submodules of $V$
. Let $C=C_G(V_1)$
. Observe that $V_1$
is a faithfully and completely reducible $G/C$
-module, while $V_2$
is a faithfully and completely reducible $C$
-module (note that $C$
is normal in $G$
). By induction,
and
Thus, $|G:G^{c}| \leq |G/C : (G/C)^{c}| \cdot |C: C^{c}| < |V_1| |V_2|=|V|$
, and we are done.
Hence, we may assume that $V$
is an irreducible $G$
-module over a finite field of characteristic $p$
. Clearly, $O_p(G)=1$
because $G$
acts faithfully on $V$
. Now the required result follows by (1).
Acknowledgements
The author's research was supported by a grant from the Simons Foundation (No 499532). The author is very grateful to the referee's helpful comments and suggestions which improve the manuscript.
