Realizing orders as group rings
Abstract
An order is a commutative ring that as an abelian group is finitely generated and free. A commutative ring is reduced if it has no non-zero nilpotent elements. In this paper we use a new tool, namely, the fact that every reduced order has a universal grading, to answer questions about realizing orders as group rings. In particular, we address the Isomorphism Problem for group rings in the case where the ring is a reduced order. We prove that any non-zero reduced order can be written as a group ring in a unique ``maximal'' way, up to isomorphism. More precisely, there exist a ring and a finite abelian group , both uniquely determined up to isomorphism, such that as rings, and such that if is a ring and is a group, then as rings if and only if there is a finite abelian group such that as rings and as groups. Computing and for given can be done by means of an algorithm that is not quite polynomial-time. We also give a description of the automorphism group of in terms of and .
Cite
@article{arxiv.2206.11001,
title = {Realizing orders as group rings},
author = {H. W. Lenstra and A. Silverberg and D. M. H. van Gent},
journal= {arXiv preprint arXiv:2206.11001},
year = {2023}
}