English

Topological Crystals

Algebraic Topology 2026-01-27 v3 Combinatorics

Abstract

Sunada's work on crystallography emphasizes the role of the "maximal abelian cover" of a graph XX. This is a covering space of XX for which the group of deck transformations is the first homology group H1(X,Z)H_1(X,\mathbb{Z}). An embedding of the maximal abelian cover in a vector space can serve as the pattern for a crystal: atoms are located at the vertices, while bonds lie along the edges. We prove that for any connected graph XX without bridges, there is a canonical embedding of the maximal abelian cover of XX into the vector space H1(X,R)H_1(X,\mathbb{R}), called a "topological crystal". Crystals of graphene and diamond are examples of this construction. We prove that any symmetry of a graph lifts to a symmetry of its topological crystal. We also compute the density of atoms in a topological crystal. The key technical tools are a way of decomposing the 1-chain coming from a path in XX into manageable pieces, and the work of Bacher, de la Harpe and Nagnibeda on integral cycles and integral cuts.

Keywords

Cite

@article{arxiv.1607.07748,
  title  = {Topological Crystals},
  author = {John C. Baez},
  journal= {arXiv preprint arXiv:1607.07748},
  year   = {2026}
}

Comments

Improved discussion of earlier work, 20 pages LaTeX with .png figures

R2 v1 2026-06-22T15:04:37.849Z