Theory of Surface Tension in Liquid Mixtures
- 1 January 1980
- journal article
- research article
- Published by Taylor & Francis in Physics and Chemistry of Liquids
- Vol. 9 (3) , 229-244
- https://doi.org/10.1080/00319108008084779
Abstract
Equations determining the density profiles of a multicomponent liquid are first given in terms of the partial direct correlation functions in the presence of the surface. The fluctuation theory of surface tension is also generalized to liquid mixtures. The density gradient procedure simplifies the above problem to knowledge of direct correlation functions in the bulk mixture. For the binary case, the density profile equations are then usefully written in terms of number-concentration correlation functions. The total density and surface segregation profiles are finally considered in a simplified model by utilizing the theory of conformal solutions. Such a model, though limited in practice, should apply, for example, to the Na-K alloy system.Keywords
This publication has 13 references indexed in Scilit:
- The statistical theory of surface tensionChemical Physics Letters, 1979
- Gradient expansion result for surface tension of binary liquid mixturesThe Journal of Chemical Physics, 1978
- Surface tension, compressibility, and surface segregation in liquid binary alloysThe Journal of Chemical Physics, 1978
- The structure of the liquid–vapor interfaceThe Journal of Chemical Physics, 1976
- A molecular theory of interfacial phenomena in multicomponent systemsThe Journal of Chemical Physics, 1976
- Generalized van der Waals theories for surface tension and interfacial widthThe Journal of Chemical Physics, 1973
- Fluctuation Theory of Surface TensionPhysical Review Letters, 1972
- Structural Aspects of the Electrical Resistivity of Binary AlloysPhysical Review B, 1970
- The statistical thermodynamics of multicomponent systemsProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1951
- The Statistical Mechanical Theory of Surface TensionThe Journal of Chemical Physics, 1949