Analytic Properties of The OCP Ionic Mixtures in the Strongly Coupled Fluid State

Methods are described for the prediction of critical loci, upper and lower critical end points, and azeotropic lines in binary and multicomponent mixtures. The results agree quantitatively with experiment for mixtures with only one liquid phase, and describe, at least qualitatively, many of the topo

Ah&act-A generalised multtiuid corresponding slates principle is presented for the correlation and prediction of the thermodynamic properties of fluid mixtures. The multifluid model is an extension of earlier work which was based on the known properties of two (nonspherical) reference fluids. The ne

The principle of corresponding states is a sound but limited principle from which to predict the thermodynamic properties of pure fluids. We describe formal extensions of the principle to cover wide classes of fluids and their mixtures. These extensions are made in a general form, from which most pr

Seven binary and three multi-component mixtures of non-ionic surfactants and a mixture of ethylene glycol and PEG 400 were investigated using tensammetry with "normal" recording and one binary mixture by using "reverse" recording. Within the initial section of the I-shaped calibration graph, the inv