Approach to equilibrium for a particle interacting with a harmonic thermal bath

Abstract

We study the long time evolution of the position-position correlation function Cα,N(s,t) for a harmonic oscillator (the probe) interacting via a coupling α with a large chain of N coupled oscillators (the heat bath). At t=0 the probe and the bath are in equilibrium at temperature TP and TB, respectively. We show that for times t and s of the order of N, Cα,N(s,t) is very well approximated by its limit Cα(s,t) as N∞. We find that, if the frequency of the probe is in the spectrum of the bath, the system appears to thermalize, at least at higher order in α. This means that, at order 0 in α, Cα(s,t) equals the correlation of a probe in contact with an ideal stochastic thermostat, that is forced by a white noise and subject to dissipation. In particular we find that t∞ Cα(t,t)=TB/2 while that τ∞ Cα(τ,τ+t) exists and decays exponentially in t. Notwithstanding this, at higher order in α, Cα(s,t) contains terms that oscillate or vanish as a power law in |t-s|. That is, even when the bath is very large, it cannot be thought of as a stochastic thermostat. When the frequency of the bath is far from the spectrum of the bath, no thermalization is observed.

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