English

Higher-rank dimer models

Combinatorics 2023-12-07 v1

Abstract

Let GG be a bipartite planar graph with edges directed from black to white. For each vertex vv let nvn_v be a positive integer. A multiweb in GG is a multigraph with multiplicity nvn_v at vertex vv. A connection is a choice of linear maps on edges Φ={ϕbw}bwE\Phi=\{\phi_{bw}\}_{bw\in E} where ϕbwHom(Rnb,Rnw)\phi_{bw}\in \mathrm{Hom}({\mathbb R}^{n_b},{\mathbb R}^{n_w}). Associated to Φ\Phi is a function on multiwebs, the trace TrΦTr_{\Phi}. We define an associated Kasteleyn matrix K=K(Φ)K=K(\Phi) in this setting and write detK\det K as the sum of traces of all multiwebs. This generalizes Kasteleyn's theorem and the result of [Douglas, Kenyon, Shi: Dimers, webs, and local systems, Trans. AMS 2023]. We study connections with positive traces, and define the associated probability measure on multiwebs. By careful choice of connection we can thus encode the "free fermionic" subvarieties for vertex models such as the 66-vertex model and 2020-vertex models, and in particular give determinantal solutions. We also find for each multiweb system an equivalent scalar system, that is, a planar bipartite graph HH and a local measure-preserving mapping from dimer covers of HH to multiwebs on GG. We identify a family of positive connections as those whose scalar versions have positive face weights.

Cite

@article{arxiv.2312.03087,
  title  = {Higher-rank dimer models},
  author = {Richard Kenyon and Nicholas Ovenhouse},
  journal= {arXiv preprint arXiv:2312.03087},
  year   = {2023}
}

Comments

38 pages

R2 v1 2026-06-28T13:42:11.097Z