Equilibrium Fluctuations for Lattice Gases

Abstract

The authors in a previous paper proved the hydrodynamic incompressible limit in d 3 for a thermal lattice gas, namely a law of large numbers for the density, velocity field and energy. In this paper the equilibrium fluctuations for this model are studied and a central limit theorem is proved for a suitable modification of the vector fluctuation field (t), whose components are the density, velocity and energy fluctuations fields. We consider a modified fluctuation field (t)= \--1t E\, where E is the linearized Euler operator around the equilibrium and prove that (t) converges to a vector generalized Ornstein-Uhlenbeck process (t), which is formally solution of the stochastic differential equation d (t)=N(t)dt+ B dWt, with BB*=-2 NC, where C is the compressibility matrix, N is a matrix whose entries are second order differential operators and B is a mean zero Gaussian field. The relation -2NC=BB* is the fluctuation-dissipation relation.

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