Metastability on the hierarchical lattice

Abstract

We study metastability for Glauber spin-flip dynamics on the N-dimensional hierarchical lattice with n hierarchical levels. Each vertex carries an Ising spin that can take the values -1 or +1. Spins interact with an external magnetic field h>0. Pairs of spins interact with each other according to a ferromagnetic pair potential J=\Ji\i=1n, where Ji>0 is the strength of the interaction between spins at hierarchical distance i. Spins flip according to a Metropolis dynamics at inverse temperature β. In the limit as β∞, we analyse the crossover time from the metastable state (all spins -1) to the stable state (all spins +1). Under the assumption that J is non-increasing, we identify the mean transition time up to a multiplicative factor 1+oβ(1). On the scale of its mean, the transition time is exponentially distributed. We also identify the set of configurations representing the gate for the transition. For the special case where Ji = J/Ni, 1 ≤ i ≤ n, with J>0 the relevant formulas simplify considerably. Also the hierarchical mean-field limit N∞ can be analysed in detail.