Powerful p-group

Last updated August 19, 2023

In mathematics, in the field of group theory, especially in the study of p-groups and pro-p-groups, the concept of powerful p-groups plays an important role. They were introduced in ( Lubotzky & Mann 1987 ), where a number of applications are given, including results on Schur multipliers. Powerful p-groups are used in the study of automorphisms of p-groups ( Khukhro 1998 ), the solution of the restricted Burnside problem ( Vaughan-Lee 1993 ), the classification of finite p-groups via the coclass conjectures ( Leedham-Green & McKay 2002 ), and provided an excellent method of understanding analytic pro-p-groups ( Dixon et al. 1991 ).

Formal definition

A finite p-group $G$ is called powerful if the commutator subgroup $[G,G]$ is contained in the subgroup $G^{p}=\langle g^{p}|g\in G\rangle$ for odd $p$ , or if $[G,G]$ is contained in the subgroup $G^{4}$ for $p=2$ .

Properties of powerful p-groups

Powerful p-groups have many properties similar to abelian groups, and thus provide a good basis for studying p-groups. Every finite p-group can be expressed as a section of a powerful p-group.

Powerful p-groups are also useful in the study of pro-p groups as it provides a simple means for characterising p-adic analytic groups (groups that are manifolds over the p-adic numbers): A finitely generated pro-p group is p-adic analytic if and only if it contains an open normal subgroup that is powerful: this is a special case of a deep result of Michel Lazard (1965).

Some properties similar to abelian p-groups are: if $G$ is a powerful p-group then:

The Frattini subgroup $\Phi (G)$ of $G$ has the property $\Phi (G)=G^{p}.$
$G^{p^{k}}=\{g^{p^{k}}|g\in G\}$ for all $k\geq 1.$ That is, the group generated by $p$ th powers is precisely the set of $p$ th powers.
If $G=\langle g_{1},\ldots ,g_{d}\rangle$ then $G^{p^{k}}=\langle g_{1}^{p^{k}},\ldots ,g_{d}^{p^{k}}\rangle$ for all $k\geq 1.$
The $k$ th entry of the lower central series of $G$ has the property $\gamma _{k}(G)\leq G^{p^{k-1}}$ for all $k\geq 1.$
Every quotient group of a powerful p-group is powerful.
The Prüfer rank of $G$ is equal to the minimal number of generators of $G.$

Some less abelian-like properties are: if $G$ is a powerful p-group then:

$G^{p^{k}}$ is powerful.
Subgroups of $G$ are not necessarily powerful.

Related Research Articles

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References

Lazard, Michel (1965), Groupes analytiques p-adiques, Publ. Math. IHÉS 26 (1965), 389–603.
Dixon, J. D.; du Sautoy, M. P. F.; Mann, A.; Segal, D. (1991), Analytic pro-p-groups, Cambridge University Press, ISBN 0-521-39580-1, MR 1152800
Khukhro, E. I. (1998), p-automorphisms of finite p-groups, Cambridge University Press, doi:10.1017/CBO9780511526008, ISBN 0-521-59717-X, MR 1615819
Leedham-Green, C. R.; McKay, Susan (2002), The structure of groups of prime power order, London Mathematical Society Monographs. New Series, vol. 27, Oxford University Press, ISBN 978-0-19-853548-5, MR 1918951
Lubotzky, Alexander; Mann, Avinoam (1987), "Powerful p-groups. I. Finite Groups", J. Algebra, 105 (2): 484–505, doi:10.1016/0021-8693(87)90211-0, MR 0873681
Vaughan-Lee, Michael (1993), The restricted Burnside problem (2nd ed.), Oxford University Press, ISBN 0-19-853786-7, MR 1364414

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Powerful p-group

Contents

Formal definition

Properties of powerful p-groups

Related Research Articles

References