Stochastic averaging for a spatial population model in random environment

Abstract

In this work we study the non-equilibrium Markov state evolution for a spatial population model on the space of locally finite configurations 2 = + × - over Rd where particles are marked by spins . Particles of type '+' reproduce themselves independently of each other and, moreover, die due to competition either among particles of the same type or particles of different type. Particles of type '-' evolve according to a non-equilibrium Glauber-type dynamics with activity z and potential . Let LS be the Markov operator for '+' -particles and LE the Markov operator for '-' -particles. The non-equilibrium state evolution (μt)t ≥ 0 is obtained from the Fokker-Planck equation with Markov operator LS + 1LE, > 0, which itself is studied in terms of correlation function evolution on a suitable chosen scale of Banach spaces. We prove that in the limiting regime 0 the state evolution μt converges weakly to some state evolution μt associated to the Fokker-Planck equation with (heuristic) Markov operator obtained from LS by averaging the interactions of the system with the environment with respect to the unique invariant Gibbs measure of the environment.