Sampling independent sets in the discrete torus

Abstract

The even discrete torus is the graph TL,d on vertex set 0,...,L-1d (L even) with two vertices adjacent if they differ by 1 (mod L) on one coordinate. The hard-core measure with activity x on TL,d is the distribution pix on the independent sets (sets of vertices spanning no edges) of TL,d in which a set I is chosen with probability proportional to x|I|. This distribution occurs in problems from statistical physics and communication networks. We study Glauber dynamics, a single-site update Markov chain on the set of independent sets of TL,d whose stationary distribution is pix. We show that for x > cd-1/4log3/4d (and d large) the convergence to stationarity is exponentially slow in Ld-1. This improves a result of Borgs et al., who had shown slow mixing for x > cd. Our proof, which extends to r-local chains (chains which alter the state of at most a proportion r of the vertices in each step) for suitable r, follows the conductance argument of Borgs et al., adding to it some combinatorial enumeration methods that are modifications of those used by Galvin and Kahn to show that the hard-core model with parameter x on the integer lattice Zd exhibits phase coexistence for x > cd-1/4log3/4d. The graph TL,d is bipartite, with partition classes E (the vertices the sum of whose coordinates is even) and O. Our result can be expressed combinatorially as the statement that for each sufficiently large x, there is an r(x)>0 such that if I is an independent set chosen according to pix, then the probability that ||I E|-|I O|| is at most r(x)Ld is exponentially small in Ld-1. In particular, for all eps>0 the probability that a uniformly chosen independent set from TL,d satisfies ||I E|-|I O|| ≤ (.25 - eps)Ld is exponentially small in Ld-1.