Dynamics of stochastic oscillator chains with harmonic and FPUT potentials

Abstract

Inspired by recent studies on deterministic oscillator models, we introduce a stochastic one-dimensional model for a chain of interacting particles. The model consists of N oscillators performing continuous-time random walks on the integer lattice Z with exponentially distributed waiting times. The oscillators are bound by confining forces to two particles that do not move, placed at positions x0 and xN+1, respectively, and they feel the presence of baths with given inverse temperatures: βL to the left, βB in the middle, and βR to the right. Each particle has an index and interacts with its nearest neighbors in index space through either a quadratic potential or a Fermi-Pasta-Ulam-Tsingou type coupling. This local interaction in index space can give rise to effective long-range interactions on the spatial lattice, depending on the instantaneous configuration. Particle hopping rates are governed either by the Metropolis rule or by a modified version that breaks detailed balance at the interfaces between regions with different baths.

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