Perturbation theory for the radial distribution function for simple polar fluids

A perturbation expupansion for the radial distribution function of fluids with nonsphericzJ pair potentials is discussed. Numerical calculations are presented for dipolar hard-sphere and quadrupolar hard-sphere fluids. Agreement with the computer simulation results is excellent, even at high dipole

Second-order Perrurb3tion theory is used fo calculate spherhi ixmnonic coefficients oi the rtn@nr pair correlation functiong(rwIw~) for a Iiquid in \ihich the molecules inreracr xxith ;\ pair porsnrial that is. the sum ot LennardJones and qwdrupotc-qu;ldrupoIr parts\_ The r&or) is cumpsred with both

The exchange energy between two atoms has been expressed in terms of a flux integral over a localized wavefunction by Holstein and Herring. By approximating this wavefunction to first order in polarization perturbation theory (Rayleigh-Schrijdinger theory) it is possible to calculate the exchange en

We present a hquid-state perturbation theory that accurately predicts the centers distribution function of a model fluid that resembles liquid nitrogen at its triple point. The theory contams no adjustable parameters and is based on physical principles.