English

Correlations in non-equilibrium diffusive systems

Statistical Mechanics 2022-08-31 v2

Abstract

We study the behavior of stationary non-equilibrium two-body correlation functions for Diffusive Systems with equilibrium reference states (DSe). We describe a DSe at the mesoscopic level by MM locally conserved continuum fields that evolve through coupled Langevin equations with white noises. The dynamic is designed such that the system may reach equilibrium states for a set of boundary conditions. In this form, we make the system driven to a non-equilibrium stationary state by changing the equilibrium boundary conditions. We decompose the correlations in a known local equilibrium part and another one that contains the non-equilibrium behavior and that we call {\it correlation's excess} Cˉ(x,z)\bar C(x,z). We formally derive the differential equations for Cˉ\bar C. To solve them order by order, we define a perturbative expansion around the equilibrium state. We show that the Cˉ\bar C's first-order expansion, Cˉ(1)\bar C^{(1)}, is always zero for the unique field case, M=1M=1. Moreover Cˉ(1)\bar C^{(1)} is always long-range or zero when M>1M>1. Surprisingly we show that their associated fluctuations, the space integrals of Cˉ(1)\bar C^{(1)}, are always zero. Therefore, fluctuations are dominated by local equilibrium up to second-order in the perturbative expansion around the equilibrium. We derive the behaviors of Cˉ(1)\bar C^{(1)} in real space for dimensions d=1d=1 and 22 explicitly. Finally, we derive the two first perturbative orders of the correlation's excess for a generic M=2M=2 case and a hydrodynamic model.

Keywords

Cite

@article{arxiv.2105.01377,
  title  = {Correlations in non-equilibrium diffusive systems},
  author = {Pedro L. Garrido},
  journal= {arXiv preprint arXiv:2105.01377},
  year   = {2022}
}

Comments

58 pages, 24 figures

R2 v1 2026-06-24T01:45:41.103Z