Metastability in a continuous mean-field model at low temperature and strong interaction

Abstract

We consider a system of N ∈ N mean-field interacting stochastic differential equations that are driven by a single-site potential of double-well form and by Brownian noise. The strength of the noise is measured by a small parameter >0 (which we interpret as the temperature), and we suppose that the strength of the interaction is given by J>0 . Choosing the empirical mean ( P:RN → R , Px =1/N Σi xi ) as the macroscopic order parameter for the system, we show that the resulting macroscopic Hamiltonian has two global minima, one at -m <0 and one at m>0 . Following this observation, we are interested in the average transition time of the system to P-1(m) , when the initial configuration is drawn according to a probability measure (the so-called last-exit distribution), which is supported around the hyperplane P-1(-m) . Under the assumption of strong interaction, J>1 , the main result is a formula for this transition time, which is reminiscent of the celebrated Eyring-Kramers formula up to a multiplicative error term that tends to 1 as N → ∞ and → 0 . The proof is based on the potential-theoretic approach to metastability. In the last chapter we add some estimates on the metastable transition time in the high temperature regime, where =1 , and for a large class of single-site potentials.