Uniqueness and Mixing in the Low-Temperature Random-Cluster Model on Trees and Random Graphs

Abstract

We study the random-cluster model on trees and treelike graphs at low temperatures. This is a model of dependent percolation parametrized by an edge probability p∈ (0,1) and a clustering weight q∈ [1,∞), generalizing independent Bernoulli percolation (q=1) and closely related to the classical ferromagnetic Ising and Potts spin systems at integer q. For q>2, approximately sampling from this model on graphs of degree at most is computationally hard. At parameter p below the tree uniqueness threshold pu(q,), it is expected that sampling is easy and local Markov chains mix rapidly on all bounded degree graphs. On typical graphs (e.g., random regular graphs), the same is predicted at p > ps(q,), where ps(q,) is a second uniqueness transition point on the -regular wired tree. Our first result establishes this non-uniqueness/uniqueness phase transition at ps(q,) for all q on the infinite -regular wired tree, resolving a conjecture of H\"aggstr\"om (1996). For this, we establish weak spatial mixing at p>ps(q,) under sufficiently wired boundary conditions. We use this understanding of decay of correlations to show that on the wired tree on n vertices, whenever q>1 and p>ps(q,), the mixing time of random-cluster Glauber dynamics is a near-optimal n1+o(1). We then extend these results on spatial and temporal mixing from the tree to treelike geometries with mostly wired boundaries and use them to show that the random-cluster Glauber dynamics mix rapidly on the random -regular graph for all p>ps(q,) as long as q C , providing an efficient sampling algorithm for both the random-cluster and Potts models in this context.