On a front evolution problem for the multidimensional East model

Abstract

We consider a natural front evolution problem the East process on Zd, d 2, a well studied kinetically constrained model for which the facilitation mechanism is oriented along the coordinate directions, as the equilibrium density q of the facilitating vertices vanishes. Starting with a unique unconstrained vertex at the origin, let S(t) consist of those vertices which became unconstrained within time t and, for an arbitrary positive direction x, let v( x),v( x ) be the maximal/minimal velocities at which S(t) grows in that direction. If x is independent of q, we prove that v( x)= v( x)(1+o(1))=γ(d) (1+o(1)) as q 0, where γ(d) is the spectral gap of the process on Zd. We also analyse the case in which some of the coordinates of x vanish as q 0. In particular, for d=2 we prove that if x approaches one of the two coordinate directions fast enough, then v( x)= v( x)(1+o(1))=γ(1) (1+o(1))=γ(d)d(1+o(1)), i.e. the growth of S(t) close to the coordinate directions is dictated by the one dimensional process. As a result the region S(t) becomes extremely elongated inside Zd+. We also establish mixing time cutoff for the chain in finite boxes with minimal boundary conditions. A key ingredient of our analysis is the renormalisation technique of arXiv:1404.7257 to estimate the spectral gap of the East process. Here we extend this technique to get the main asymptotics of a suitable principal Dirichlet eigenvalue of the process.

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