Thermodynamic properties of nitrogen from a perturbation theory for ISM fluids

A~traet--In this paper, we present a first-order hard sphere perturbation theory of nonideal ternary fluid mixtures. Results are reported for total and excess thermodynamic properties of three ternary mixtures, in which size parameters of the mixture components are the same, but energy parameters di

In this paper, a previously developed first-order hard sphere perturbation theory of a ternary fluid mixture (Fotouh and Shukla, 1996, Chem. Enyn9 Sci. 51, 49234931) is applied to predict excess properties of a real ternary fluid mixture using a theoretically consistent combination rule. We consider

A recent paper [ 1] examined the effect of polarizability in a liquid of polar spheres by using first-order perturbation theory. A Monte Carlo calculation was

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.

more inert, large glass spheres should be underestimated. However, as shown in Fig. , this is not the case. Thus, even under these conditions, the determination seems to be representative. As a consequence, it is possible to investigate the shape of the distribution in the detectable range. In the