Finitary codings for the random-cluster model and other infinite-range monotone models

Abstract

A random field X = (Xv)v ∈ G on a quasi-transitive graph G is a factor of i.i.d. if it can be written as X=(Y) for some i.i.d. process Y= (Yv)v ∈ G and equivariant map . Such a map, also called a coding, is finitary if, for every vertex v ∈ G, there exists a finite (but random) set U ⊂ G such that Xv is determined by \Yu\u ∈ U. We construct a coding for the random-cluster model on G, and show that the coding is finitary whenever the free and wired measures coincide. This strengthens a result of H\"aggstr\"om--Jonasson--Lyons. We also prove that the coding radius has exponential tails in the subcritical regime. As a corollary, we obtain a similar coding for the subcritical Potts model. Our methods are probabilistic in nature, and at their heart lies the use of coupling-from-the-past for the Glauber dynamics. These methods apply to any monotone model satisfying mild technical (but natural) requirements. Beyond the random-cluster and Potts models, we describe two further applications -- the loop O(n) model and long-range Ising models. In the case of G = Zd, we also construct finitary, translation-equivariant codings using a finite-valued i.i.d. process Y. To do this, we extend a mixing-time result of Martinelli--Olivieri to infinite-range monotone models on quasi-transitive graphs of sub-exponential growth.