Mesoscopic simulation method for liquid-vapor phase transition

摘要

A mesoscopic simulation method for liquid-vapor phase transition: Short-range repulsive intermolecular interaction is incorporated by equation of state for dense gas, long-range attractive intermolecular interaction is mimicked by pairwise interaction force, density distribution function is used to handle mass-momentum conservation laws, and total kinetic energy distribution function is used to handle energy conservation law. Lattice Boltzmann equation for density distribution function recovers the equation of state for dense gas and pairwise interaction force. Lattice Boltzmann equation for total kinetic energy distribution function recovers viscous dissipation, compression work, and works done by the pairwise interaction force and surface tension. The method has microscopic particle picture, mesoscopic kinetic background, conceptual and computational simplicity, wide applicability, and high reliability. The method is kinetically and thermodynamically consistent and allows direct numerical simulations of liquid-vapor phase transition processes.