Netsu Sokutei Volume 30, Issue 2

Mixing Schemes in Binary Aqueous Solutions of Non-electrolytes

Our thermodynamic studies on Mixing Schemes operating in aqueous solutions of nonelectrolytes are reviewed. We use the data of higher order of G than hitherto utilized. Generally there are three distinctively different Mixing Schemes present over the entire composition range. Some details of each Mixing Schemes are described as much as known at this time. The findings by other techniques are also discussed where applicable.

Theoretical Estimations of Thermodynamic Quantities of Solutions by using the Integral Equation Theory

If we want to get the deep understandings for the behavior of thermodynamic quantities of solutions in connection with its microscopic structure, we must proceed to the collaboration of experimental study with theoretical ones. In this article, the outline of the integral equation theory of solutions is described, because the integral equation theory is the representative theory to describe the structure and thermodynamic properties of solutions on the same theoretical bases. At first, the basic properties of distribution functions are discussed. Next, the relations of thermodynamic quantities with the distribution functions and the integral equations on the distribution functions are summarized. Finally, calculated results are shown in the cases of excess enthalpies and partial molar enthalpies of binary mixtures as an example of an attempt to construct the intuitive image for the behavior of solutions on the rigorous theoretical basis.

Excess Thermodynamic Functions of Binary Liquid Mixtures Using Rayleigh Laser Light Scattering

Rayleigh light scattering ratios obtained using a laser light source, combined with molar volume and refractive index measurements, were used to evaluate the excess Gibbs potentials of mixing in binary liquid mixtures. When these quantities are measured as functions of temperature, as well as composition, the excess enthalpy and entropy of the binary mixtures can be obtained. This contribution presents the pertinent experimental techniques and data analyses necessary to extract excess Gibbs potentials from light scattering measurements. Data is presented for one representative system consisting of toluene and propan-2-ol mixtures.