Macroscopic loops in the $3d$ double-dimer model
Abstract
The double dimer model is defined as the superposition of two independent uniformly distributed dimer covers of a graph. Its configurations can be viewed as disjoint collections of self-avoiding loops. Our first result is that in , , the loops in the double dimer model are macroscopic. These are shown to behave qualitatively differently than in two dimensions. In particular, we show that, given two distant points of a large box, with uniformly positive probability there exists a loop visiting both points. Our second result involves the monomer double-dimer model, namely the double-dimer model in the presence of a density of monomers. These are vertices which are not allowed to be touched by any loop. This model depends on a parameter, the monomer activity, which controls the density of monomers. It is known from Betz and Taggi (2019) and Taggi (2021) that a finite critical threshold of the monomer activity exists, below which a self-avoiding walk forced through the system is macroscopic. Our paper shows that, when , such a critical threshold is strictly positive. In other words, the self-avoiding walk is macroscopic even in the presence of a positive density of monomers.
Keywords
Cite
@article{arxiv.2206.08284,
title = {Macroscopic loops in the $3d$ double-dimer model},
author = {Alexandra Quitmann and Lorenzo Taggi},
journal= {arXiv preprint arXiv:2206.08284},
year = {2023}
}
Comments
11 pages, 1 figure, minor modifications, accepted for publication in ECP