Resonant Response in Non-equilibrium Steady States

TL;DR

This paper investigates how non-equilibrium systems exhibit resonant responses when driven at specific frequencies related to their eigenvalues, providing explicit formulas and numerical validation for these phenomena.

Contribution

It formally proves the resonance phenomenon in non-equilibrium steady states and derives an explicit formula for frequency-dependent mobility.

Findings

Resonance occurs when driving frequency matches eigenvalue imaginary parts.

Explicit formula for frequency-dependent mobility is derived.

Numerical simulations confirm theoretical predictions.

Abstract

The time-dependent probability density function of a system evolving towards a stationary state exhibits an oscillatory behavior if the eigenvalues of the corresponding evolution operator are complex. The frequencies \omega_n, with which the system reaches its stationary state, correspond to the imaginary part of such eigenvalues. If the system is further driven by a small and oscillating perturbation with a given frequency \omega, we formally prove that the linear response to the probability density function is enhanced when \omega = \omega_n. We prove that the occurrence of this phenomenon is characteristic of systems that reach a non-equilibrium stationary state. In particular we obtain an explicit formula for the frequency-dependent mobility in terms of the of the relaxation to the stationary state of the (unperturbed) probability current. We test all these predictions by means of numerical simulations considering an ensemble of non-interacting overdamped particles on a tilted periodic potential.