The mixing time of the lozenge tiling Glauber dynamics

Abstract

The broad motivation of this work is a rigorous understanding of reversible, local Markov dynamics of interfaces, and in particular their speed of convergence to equilibrium, measured via the mixing time Tmix. In the (d+1)-dimensional setting, d2, this is to a large extent mathematically unexplored territory, especially for discrete interfaces. On the other hand, on the basis of a mean-curvature motion heuristics and simulations, one expects convergence to equilibrium to occur on time-scales of order ≈ δ-2 in any dimension, with δ0 the lattice mesh. We study the single-flip Glauber dynamics for lozenge tilings of a finite domain of the plane, viewed as (2+1)-dimensional surfaces. The stationary measure is the uniform measure on admissible tilings. At equilibrium, by the limit shape theorem, the height function concentrates as δ0 around a deterministic profile φ, the unique minimizer of a surface tension functional. Despite some partial mathematical results, the conjecture Tmix=δ-2+o(1) has been proven, so far, only in the situation where φ is an affine function. In this work, we prove the conjecture under the sole assumption that the limit shape φ contains no frozen regions (facets).

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