Nonequilibrium statistical mechanics of weakly stochastically perturbed system of oscillators

Abstract

We consider a finite region of a d-dimensional lattice, d∈N, of weakly coupled harmonic oscillators. The coupling is provided by a nearest-neighbour potential (harmonic or not) of size . Each oscillator weakly interacts by force of order with its own stochastic Langevin thermostat of arbitrary positive temperature. We investigate limiting as → 0 behaviour of solutions of the system and of the local energy of oscillators on long-time intervals of order -1 and in a stationary regime. We show that it is governed by an effective equation which is a dissipative SDE with nondegenerate diffusion. Next we assume that the interaction potential is of size λ, where λ is another small parameter, independent from . Solutions corresponding to this scaling describe small low temperature oscillations. We prove that in a stationary regime, under the limit → 0, the main order in λ of the averaged Hamiltonian energy flow is proportional to the gradient of temperature. We show that the coefficient of proportionality, which we call the conductivity, admits a representation through stationary space-time correlations of the energy flow. Most of the results and convergences we obtain are uniform with respect to the number of oscillators in the system.