Gigahertz elastic modulus and OH stretching frequency correlate with Jones–Dole’s B-coefficient in aqueous solutions of the Hofmeister series

Abstract

The ability of salts to change the macroscopic viscosity of their aqueous solutions is described by the Jones–Dole equation with B-coefficient for the linear concentration term. The sign and value of this coefficient are often considered as a measure of the salt’s structure-making/breaking ability, while the validity of this assignment is still under discussion. Here, by applying Raman and Brillouin scattering spectroscopy to various salts from the Hofmeister series, we studied a possible relation between macroscopic Jones–Dole’s B-coefficient and the microscopic dynamic response. Raman spectroscopy provides information about molecular vibrations and Brillouin spectroscopy about acoustic phonons with wavelengths of hundreds of nanometers. It has been found that Jones–Dole’s B-coefficient correlates linearly with the coefficients, describing the concentration dependences of the average OH stretching frequency, real and imaginary parts of gigahertz elastic modulus. These relationships have been interpreted to mean that the OH stretching frequency is a measure of the ion-induced changes in the water network that cause changes in both viscosity and gigahertz relaxation. Depolarized inelastic light scattering revealed that the addition of structure-making ions not only changes the frequency of the relaxation peak but also increases the low-frequency part of the relaxation susceptibility. It was shown that the ion-induced increase in the gigahertz elastic modulus can be described by changes in the relaxational susceptibility without a noticeable change in the instantaneous elastic modulus. The isotropic Raman contribution associated with the tetrahedral-like environment of H2O molecule does not correlate with Jones–Dole’s B-coefficient, suggesting a minor influence of these tetrahedral-like configurations on viscosity.