The Multiple Holomorphs of Finite p-Groups of Class Two

Abstract

HolAut[0]G(p)[1] #1 Let G be a group, and S(G) be the group of permutations on the set G. The (abstract) holomorph of G is the natural semidirect product (G) G. We will write (G) for the normalizer of the image in S(G) of the right regular representation of G, equation* (G) = NS (G)((G)) = (G) (G) (G) G, equation* and also refer to it as the holomorph of G. More generally, if N is any regular subgroup of S(G), then NS(G)(N) is isomorphic to the holomorph of N. G.A.~Miller has shown that the group equation* T(G) = NS(G)((G))/(G) equation* acts regularly on the set of the regular subgroups N of S(G) which are isomorphic to G, and have the same holomorph as G, in the sense that NS(G)(N) = (G). If G is non-abelian, inversion on G yields an involution in T(G). Other non-abelian regular subgroups N of S(G) having the same holomorph as G yield (other) involutions in T(G). In the cases studied in the literature, T(G) turns out to be a finite 2-group, which is often elementary abelian. In this paper we exhibit an example of a finite p-group of class 2, for p > 2 a prime, which is the smallest p-group such that T() is non-abelian, and not a 2-group. Moreover, T() is not generated by involutions when p > 3. More generally, we develop some aspects of a theory of T(G) for G a finite p-group of class 2, for p > 2. In particular, we show that for such a group G there is an element of order p-1 in T(G), and exhibit examples where T(G) = p - 1, and others where T(G) contains a large elementary abelian p-subgroup.