Rigorous resolution of the hierarchy of grand-canonical-ensemble Green functions

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

The grand-canonical ensemble is used to derive fluctuation formulae for the particle densities, the pressure and the energy density of a multi-component ionic mixture. As an intermediate step sum rules are established for the two-particle Ursell functions.

The generating functional of the lsing model is studied. Equations of motion for the generating functional and the hierarchy of Green's functions are derived. These equations resemble a scalar field theory with nonlinear derivative coupling. Such a formulation bridges the gap between the Ising model

A new simulation method is introduced for the determination of the vapour-liquid phase separation of pure fluids in the grand canonical ensemble. It is based on the third-order Taylor series of the pressure with respect to the reciprocal temperature term ([3 = 1/kT) and the configurational chemical