Periodic Euclidean Graphs on Integer Points
Abstract
A uniformly discrete Euclidean graph is a graph embedded in a Euclidean space so that there is a minimum distance between distinct vertices. If such a graph embedded in an -dimensional space is preserved under linearly independent translations, it is "-periodic" in the sense that the quotient group of its symmetry group divided by the translational subgroup of its symmetry group is finite. We present a refinement of a theorem of Bieberbach: given a -periodic uniformly discrete Euclidean graph embedded in a -dimensional Euclidean space of symmetry group , there is another -periodic uniformly discrete Euclidean graph embedded in the same space whose vertices are integer points (possibly modulo an affine transformation) and whose symmetry group has a (not necessarily proper) subgroup isomorphic to . We conclude with a discussion of an application to the computer generation of "crystal nets".
Keywords
Cite
@article{arxiv.1105.2328,
title = {Periodic Euclidean Graphs on Integer Points},
author = {Gregory McColm},
journal= {arXiv preprint arXiv:1105.2328},
year = {2016}
}
Comments
Withdrawn by author as there are problems with Claim 2.1 and Construction 3.3; Repairs made and Revision posted