English

Diffusion approximation for equilibrium Kawasaki dynamics in continuum

Probability 2007-08-20 v2 Mathematical Physics math.MP

Abstract

A Kawasaki dynamics in continuum is a dynamics of an infinite system of interacting particles in Rd\mathbb R^d which randomly hop over the space. In this paper, we deal with an equilibrium Kawasaki dynamics which has a Gibbs measure μ\mu as invariant measure. We study a diffusive limit of such a dynamics, derived through a scaling of both the jump rate and time. Under weak assumptions on the potential of pair interaction, ϕ\phi, (in particular, admitting a singularity of ϕ\phi at zero), we prove that, on a set of smooth local functions, the generator of the scaled dynamics converges to the generator of the gradient stochastic dynamics. If the set on which the generators converge is a core for the diffusion generator, the latter result implies the weak convergence of finite-dimensional distributions of the corresponding equilibrium processes. In particular, if the potential ϕ\phi is from Cb3(Rd)C_{\mathrm b}^3(\mathbb R^d) and sufficiently quickly converges to zero at infinity, we conclude the convergence of the processes from a result in [Choi {\it et al.}, J. Math. Phys. 39 (1998) 6509--6536].

Keywords

Cite

@article{arxiv.math/0702178,
  title  = {Diffusion approximation for equilibrium Kawasaki dynamics in continuum},
  author = {Y. G. Kondratiev and O. V. Kutoviy and E. W. Lytvynov},
  journal= {arXiv preprint arXiv:math/0702178},
  year   = {2007}
}