Nonuniform fluids in the grand canonical ensemble

In this article the Taylor-expansion method is introduced by which Monte Carlo ( \(\mathrm{MC}\) ) simulations in the canonical ensemble can be speeded up significantly. Substantial gains in computational speed of \(20-40 \%\) over conventional implementations of the \(M C\) technique are obtained o

## Abstract An extended system Hamiltonian is proposed to perform molecular dynamics (MD) simulation in the grand canonical ensemble. The Hamiltonian is similar to the one proposed by Lynch and Pettitt (Lynch and Pettitt, J Chem Phys 1997, 107, 8594), which consists of the kinetic and potential ene

Results are presented for the effect of periodic boundary conditions on predictions made using the grand canonical ensemble for systems of limited size. A Monte Carlo study of a realistic gas-solid adsorption model and an exact study of the Tonks gas both show that it is necessary for the minor dime

The Fourier path integral formalism was implemented in the grand canonical ensemble and applied to a two-dimensional Lennard-Jones fluid, which is used to model a quantum monolayer. The method was employed to obtain the variation in the density of the monolayer as a function of chemical activity at

## Abstract By generalizing the integration by parts formula on the function space, the isomorphism between the general class of selfinteracting Euclidean, Bose fields and classical gases is proven in a nonperturbative way. Rigorous, non‐perturbative derivations of the Mayer equations and Bogoliubo