%0 Journal Article %1 Lencka1998 %A Lencka, M. M. %A Anderko, A. %A Sanders, S. J. %A Young, R. D. %D 1998 %J International Journal of Thermophysics %K 1998 viscosity aqueous electrolyte multi-component %N 2 %P 367--378 %T Modeling Viscosity of Multicomponent Electrolyte Solutions %U http://dx.doi.org/10.1023/A:1022501108317 %V 19 %X A comprehensive model for calculating the viscosity of aqueous electrolyte solutions has been developed. The model includes a long-range electrostatic interaction term, contributions of individual ions, and a contribution of specific interactions between ions or neutral species. The long-range electrostatic term is obtained from the Onsager–Fuoss theory, whereas the individual ionic contributions are calculated using the Jones–Dole B coefficients. A technique for predicting the temperature dependence of the B coefficients has been developed on the basis of the concept of structure-breaking and structure-making ions. The contribution of specific interactions between species, which is dominant for concentrated solutions, has been found to be a function of the ionic strength. The model reproduces the viscosity of aqueous systems ranging from dilute to concentrated solutions (up to ca. 30m) at temperatures up to 573 K with an accuracy that is appropriate for modeling industrially important systems. In particular, the viscosity of multicomponent systems can be accurately predicted using parameters obtained from single-solute systems.

@article{Lencka1998, abstract = {A comprehensive model for calculating the viscosity of aqueous electrolyte solutions has been developed. The model includes a long-range electrostatic interaction term, contributions of individual ions, and a contribution of specific interactions between ions or neutral species. The long-range electrostatic term is obtained from the Onsager–Fuoss theory, whereas the individual ionic contributions are calculated using the Jones–Dole B coefficients. A technique for predicting the temperature dependence of the B coefficients has been developed on the basis of the concept of structure-breaking and structure-making ions. The contribution of specific interactions between species, which is dominant for concentrated solutions, has been found to be a function of the ionic strength. The model reproduces the viscosity of aqueous systems ranging from dilute to concentrated solutions (up to ca. 30m) at temperatures up to 573 K with an accuracy that is appropriate for modeling industrially important systems. In particular, the viscosity of multicomponent systems can be accurately predicted using parameters obtained from single-solute systems.}, added-at = {2011-01-19T18:06:43.000+0100}, author = {Lencka, M. M. and Anderko, A. and Sanders, S. J. and Young, R. D.}, biburl = {https://www.bibsonomy.org/bibtex/2be1de51bff5a0e1f171e1d70258f39d2/thorade}, description = {SpringerLink - Zeitschriftenbeitrag}, interhash = {fc686de2dcac0cc11b1c177f1809a110}, intrahash = {be1de51bff5a0e1f171e1d70258f39d2}, journal = {International Journal of Thermophysics}, keywords = {1998 viscosity aqueous electrolyte multi-component}, month = {03}, number = 2, pages = {367--378}, timestamp = {2012-03-15T16:14:08.000+0100}, title = {Modeling Viscosity of Multicomponent Electrolyte Solutions}, url = {http://dx.doi.org/10.1023/A:1022501108317}, volume = 19, year = 1998 }