Convection Patterns in Nonequilibrium Kawasaki Dynamics at Low Temperature

TL;DR

This paper investigates how nonequilibrium convection patterns emerge in a low-temperature Kawasaki dynamics system with spatially varying temperature, revealing novel stripe structures and developing a macroscopic theory to explain these phenomena.

Contribution

It introduces a new understanding of convection patterns in nonequilibrium Kawasaki dynamics with spatially varying temperature fields, contrasting with equilibrium behaviors.

Findings

Robust convection stripe patterns form at low temperatures under nonequilibrium conditions.

These patterns differ significantly from equilibrium phase separation.

A macroscopic framework successfully describes the observed convection phenomena.

Abstract

We study a conservative stochastic lattice dynamics (Kawasaki dynamics) in contact everywhere in the bulk with a heat bath. Particles interact via an Ising Hamiltonian and phase separation occurs at low temperature. We drive the system out of equilibrium by imposing a temperature field that varies spatially on macroscopic scales while preserving local equilibrium. Under these conditions, the usual low-temperature long-range order is replaced by robust convection patterns, featuring regularly spaced stripe structures for suitable geometries. These nonequilibrium states differ markedly from those obtained in an equilibrium dynamics with the same local temperature profile. We develop a macroscopic description that captures these behaviors and provides a unified framework for understanding the observed patterns.