On a Class of Self-Similar Polycyclic Groups
Abstract
A group G is self-similar if it admits a triple (G,H,f) where H is a subgroup of G and f: H G a simple homomorphism, that is, the only subgroup K of H, normal in G and f-invariant (Kf ≤ K) is trivial. The group G then has two chains of subgroups: \[ G0 = G,\ H0 = H,\ Gk = (Hk-1)f,\ Hk = H Gk\ for (k ≥ 1). \] We define a family of self-similar polycyclic groups, denoted SSP, where each subgroup Gk is self-similar with respect to the triple (Gk , Hk, f) for all k. By definition, a group G belongs to this SSP family provided f: H → G is a monomorphism, Hk and Gk+1 are normal subgroups of index p in Gk (p a prime or infinite) and Gk=HkGk+1. When G is a finite p-group in the class SSP, we show that the above conditions follow simply from [G:H] = p and f is a simple monomorphism. We show that if the Hirsch length of G is n, then G has a polycyclic generating set \a1, …, an\ which is self-similar under the action of f: a1 → a2 → … → an, and then G is either a finite p-group or is torsion-free. Surprisingly, the arithmetic of n modulo 3 has a strong impact on the structure of G. This fact allows us to prove that G is nilpotent metabelian whose center is free p-abelian (p prime or infinite) of rank at least n/3. We classify those groups G where H has nilpotency class at most 2. Furthermore, when p=2, we prove that G is a finite 2-group of nilpotency class at most 2, and classify all such groups.
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