Torsion-free crystallographic groups with indecomposable holonomy group
Abstract
Let K be a principal ideal domain, G a finite group, and M a KG-module which as K-module is free of finite rank, and on which G acts faithfully. A generalized crystallographic group (introduced by the authors in volume 5 of Journal of Group Theory) is a group C which has a normal subgroup isomorphic to M with quotient G, such that conjugation in C gives the same action of G on M that we started with. (When K= Z, these are just the classical crystallographic groups.) The K-free rank of M is said to be the dimension of C, the holonomy group of C is G, and C is called indecomposable if M is an indecomposable KG-module. Let K be either Z, or its localization Z(p) at the prime p, or the ring Zp of p-adic integers, and consider indecomposable torsionfree generalized crystallographic groups whose holonomy group is noncyclic of order p2. In Theorem 2, we prove that (for any given p) the dimensions of these groups are not bounded. For K= Z, we show in Theorem 3 that there are infinitely many non-isomorphic indecomposable torsionfree crystallographic groups with holonomy group the alternating group of degree 4. In Theorem 1, we look at a cyclic G whose order |G| satisfies the following condition: for all prime divisors p of |G|, p2 also divides G, and for at least one p, even p3 does. We prove that then every product of |G| with a positive integer coprime to it occurs as the dimension of some indecomposable torsionfree crystallographic group with holonomy group G.
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