Steady-state properties of a finite system driven by a chemical-potential gradient

23 July 1990

journal article
research article
Published by American Physical Society (APS) in Physical Review Letters

Vol. 65 (4) , 440-443
https://doi.org/10.1103/physrevlett.65.440

Abstract

A two-dimensional lattice-gas model with repulsive interactions periodically infinite in one dimension and finite in the other is driven into a mass-transporting steady state by asymmetric chemical potentials applied at the open edges. By computer-simulation techniques the steady-state current, the mass profile, and the order-parameter profile are calculated. The driven system is found to display a nonequilibrium phase behavior controlled by the mass flux.

Keywords

This publication has 12 references indexed in Scilit:

Kinetics of diffusion-controlled oxygen ordering in a lattice-gas model of ${YBa}_{2}$ ${Cu}_{3}$ $O_{7 - δ}$
Physical Review B, 1990
Ginzburg-Landau theory for mass transport in a driven diffusive system
Physical Review B, 1990
Roughness, spatial, and temporal correlations of an interface in a driven nonequilibrium lattice gas
Physical Review B, 1989
Phase transitions in a driven lattice gas with repulsive interactions
Physical Review Letters, 1989
Thermal conductivity of a kinetic ising model
Physical Review B, 1988
Suppression of Interface Roughness in Driven Nonequilibrium Systems
Physical Review Letters, 1988
Field theory of critical behaviour in driven diffusive systems
Zeitschrift für Physik B Condensed Matter, 1986
Phase Transitions in Lattice-Gas Models Far from Equilibrium
Physical Review Letters, 1984
Diffusion of absorbed atoms in ordered and disordered monolayers at surfaces
Surface Science, 1983
Phase transitions in stationary nonequilibrium states of model lattice systems
Physical Review B, 1983