Phase transitions in driven lattice gases
- 1 June 1996
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review E
- Vol. 53 (6) , 6038-6047
- https://doi.org/10.1103/physreve.53.6038
Abstract
We have studied nonequilibrium lattice gases whose particles are driven by a field. The lattice is either a half-occupied square lattice or else the union of two energetically uncoupled ones. Monte Carlo simulations of the latter, which is always crossed by a dissipative particle current, show a tricritical point and a continuum of Ising-like critical points as the field is decreased, in addition to non-Ising, anisotropic critical behavior at higher temperatures for saturating fields. A comparison of the various phase transitions involved, and a detailed study of scaling of correlations with system size, indicate the relevance of the anisotropic liquid-vapor interface (rather than the driving field) for inducing non-Ising behavior in a class of systems. It is likely that some of the properties reported here are experimentally observable. © 1996 The American Physical Society.Keywords
This publication has 27 references indexed in Scilit:
- Non-equilibrium layered lattice gasesJournal of Physics A: General Physics, 1995
- Phase transitions in a driven lattice gas in two planesJournal of Statistical Physics, 1995
- Lattice-gas models of phase separation: interfaces, phase transitions, and multiphase flowReviews of Modern Physics, 1994
- Pattern formation outside of equilibriumReviews of Modern Physics, 1993
- Nonequilibrium steady states and phase transitions in driven diffusive systemsAnnals of Physics, 1990
- Field theory of critical behaviour in driven diffusive systemsZeitschrift für Physik B Condensed Matter, 1986
- Field theory of critical behavior in a driven diffusive systemJournal of Statistical Physics, 1986
- Critical behaviour in a model of stationary flow and supersymmetry breakingNuclear Physics B, 1986
- Nonequilibrium steady states of stochastic lattice gas models of fast ionic conductorsJournal of Statistical Physics, 1984
- Solid electrolytes—the beta aluminasPhysics Today, 1982