Spatial Mixing and Systematic Scan Markov chains

Abstract

We consider spin systems on the integer lattice graph Zd with nearest-neighbor interactions. We develop a combinatorial framework for establishing that exponential decay with distance of spin correlations, specifically the strong spatial mixing condition (SSM), implies rapid mixing of a large class of Markov chains. As a first application of our method we prove that SSM implies O( n) mixing of systematic scan dynamics (under mild conditions) on an n-vertex d-dimensional cube of the integer lattice graph Zd. Systematic scan dynamics are widely employed in practice but have proved hard to analyze. A second application of our technology concerns the Swendsen-Wang dynamics for the ferromagnetic Ising and Potts models. We show that SSM implies an O(1) bound for the relaxation time (i.e., the inverse spectral gap). As a by-product of this implication we observe that the relaxation time of the Swendsen-Wang dynamics in square boxes of Z2 is O(1) throughout the subcritical regime of the q-state Potts model, for all q 2. We also use our combinatorial framework to give a simple coupling proof of the classical result that SSM entails optimal mixing time of the Glauber dynamics. Although our results in the paper focus on d-dimensional cubes in Zd, they generalize straightforwardly to arbitrary regions of Zd and to graphs with subexponential growth.