Density-functional theory of simple classical fluids. I. Surfaces

1 December 1976

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

Vol. 14 (6) , 2264-2273
https://doi.org/10.1103/physreva.14.2264

Abstract

A density-functional theory appropriate to nonuniform simple classical fluids is developed. Unlike most previous theories, the theory is in principle exact in the linear-response regime. For practical applications a small number of well-defined approximations, including that of Percus and Yevick, are made. Given only the Lennard-Jones 6-12 potential as input, the theory yields surface tensions and profiles in very good agreement with the results of Monte Carlo calculations. For a liquid pressed against a hard wall the expected oscillations in density in the vicinity of the wall are obtained. Comparisons with previous theories are made, and points of possible improvement in the formalism are discussed.

Keywords

This publication has 30 references indexed in Scilit:

Modified Van der Waals theory of fluid interfaces
Physical Review A, 1975
Renormalized density-functional theory of nonuniform superfluid ${}^{4}{He}$ at zero temperature
Physical Review B, 1975
On the structure of a free surface of a Lennard-Jones liquid: A Monte Carlo calculation
The Journal of Chemical Physics, 1975
Surface-Mode Renormalized Density-Functional Theory of the Free Surface of ${}^{4}{He}$
Physical Review Letters, 1975
Computer simulation of the gas/liquid surface
Faraday Discussions of the Chemical Society, 1975
Phase separation of Lennard-Jones systems: A film in equilibrium with vapor
The Journal of Chemical Physics, 1974
Surface structure and surface tension: Perturbation theory and Monte Carlo calculation
The Journal of Chemical Physics, 1974
Statistical thermodynamics of the liquid surface
Advances in Physics, 1973
Statistical mechanical and quasithermodynamic calculations of surface densities and surface tension
Molecular Physics, 1973
Perturbation Theory for Nonuniform Fluids: Surface Tension
The Journal of Chemical Physics, 1971