Logarithmic Mixing of Random Walks on Dynamical Random Cluster Models

Abstract

We study random walks on dynamically evolving graphs, where the environment is given by a time-dependent subset of the edges of an underlying graph. Concretely, following the recently introduced framework of Lelli and Stauffer, we consider a random walk interacting with a dynamical random-cluster environment, in which edges are updated with rate μ>0 according to Glauber dynamics with parameters p and q, and the walker moves at rate 1 but may only traverse edges that are present at the time of the move. This setting introduces strong dependencies between the walk and the environment, as edge-update probabilities depend on the global connectivity structure. We focus on the case where the underlying graph is a random d-regular graph and the parameters lie in the subcritical regime p < pu(q, d) where it is known that the Glauber dynamics mixes quickly. Our main result is to show that for any >0 and all q 1, for all p in the subcritical regime, the mixing time of the joint process is ( n) (in continuous time) whenever μ≥ n. This matches the mixing time of the simple random walk on a static random regular graph, showing that in this regime the evolving environment does not slow down mixing. Our proof is based on a coupling argument that uses path-count techniques to overcome the dependencies in the edge dynamics by controlling the structure of the environment along typical trajectories.