Surface Tension Models for Binary Aqueous Solutions: a Review and Intercomparison

Overview

Journal Phys Chem Chem Phys

Publisher Royal Society of Chemistry

Specialties Biophysics
Chemistry

Date 2023 Apr 11

PMID 37039675

Authors

Judith Kleinheins

Nadia Shardt

Manuella El Haber

Corinne Ferronato

Barbara Noziere

Thomas Peter

Claudia Marcolli

Affiliations

Soon will be listed here.

Abstract

The liquid-air surface tension of aqueous solutions is a fundamental quantity in multi-phase thermodynamics and fluid dynamics and thus relevant in many scientific and engineering fields. Various models have been proposed for its quantitative description. This Perspective gives an overview of the most popular models and their ability to reproduce experimental data of ten binary aqueous solutions of electrolytes and organic molecules chosen to be representative of different solute types. In addition, we propose a new model which reproduces sigmoidal curve shapes (Sigmoid model) to empirically fit experimental surface tension data. The surface tension of weakly surface-active substances is well reproduced by all models. In contrast, only few models successfully model the surface tension of aqueous solutions with strongly surface-active substances. For substances with a solubility limit, usually no experimental data is available for the surface tension of supersaturated solutions and the pure liquid solute. We discuss ways in which these can be estimated and emphasize the need for further research. The newly developed Sigmoid model best reproduces the surface tension of all tested solutions and can be recommended as a model for a broad range of binary mixtures and over the entire concentration range.

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