Modeling the Dynamic Viscosity of Ionic Solutions

Aimee Ruiz-Llamas; Ricardo Macías-Salinas

doi:10.1021/acs.iecr.5b01664

Modeling the Dynamic Viscosity of Ionic Solutions

Aimee Ruiz-Llamas, Ricardo Macías-Salinas

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

In the present work, an Eyring-theory model based on concepts of excess Gibbs energy of activation of the viscous flow has been developed for the accurate correlation or prediction of the dynamic viscosity of ionic solutions: inorganic salt (electrolyte) + solvent and organic salt (ionic liquid) + solvent. For the excess Gibbs energy of activation (G^EX,≠), both thermal and mechanical contributions to the viscous flow were considered. Accordingly, a thermal G^EX,≠ term was described by mixing rules of the Redlich-Kister-type, whereas the mechanical G^EX,≠ term was computed from a simple cubic equation of state in an attempt to overall represent the main molecular interactions (between the ionic species and the solvent) affecting viscosity. The resulting model was successfully validated during the representation of experimental dynamic viscosities of various nonaqueous and aqueous ionic solutions within wide ranges of temperature and composition (or salt molality).

Original language	English
Pages (from-to)	7169-7179
Number of pages	11
Journal	Industrial and Engineering Chemistry Research
Volume	54
Issue number	28
DOIs	https://doi.org/10.1021/acs.iecr.5b01664
State	Published - 22 Jul 2015
Externally published	Yes

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title = "Modeling the Dynamic Viscosity of Ionic Solutions",

abstract = "In the present work, an Eyring-theory model based on concepts of excess Gibbs energy of activation of the viscous flow has been developed for the accurate correlation or prediction of the dynamic viscosity of ionic solutions: inorganic salt (electrolyte) + solvent and organic salt (ionic liquid) + solvent. For the excess Gibbs energy of activation (GEX,≠), both thermal and mechanical contributions to the viscous flow were considered. Accordingly, a thermal GEX,≠ term was described by mixing rules of the Redlich-Kister-type, whereas the mechanical GEX,≠ term was computed from a simple cubic equation of state in an attempt to overall represent the main molecular interactions (between the ionic species and the solvent) affecting viscosity. The resulting model was successfully validated during the representation of experimental dynamic viscosities of various nonaqueous and aqueous ionic solutions within wide ranges of temperature and composition (or salt molality).",

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AU - Macías-Salinas, Ricardo

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AB - In the present work, an Eyring-theory model based on concepts of excess Gibbs energy of activation of the viscous flow has been developed for the accurate correlation or prediction of the dynamic viscosity of ionic solutions: inorganic salt (electrolyte) + solvent and organic salt (ionic liquid) + solvent. For the excess Gibbs energy of activation (GEX,≠), both thermal and mechanical contributions to the viscous flow were considered. Accordingly, a thermal GEX,≠ term was described by mixing rules of the Redlich-Kister-type, whereas the mechanical GEX,≠ term was computed from a simple cubic equation of state in an attempt to overall represent the main molecular interactions (between the ionic species and the solvent) affecting viscosity. The resulting model was successfully validated during the representation of experimental dynamic viscosities of various nonaqueous and aqueous ionic solutions within wide ranges of temperature and composition (or salt molality).

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JO - Industrial and Engineering Chemistry Research

JF - Industrial and Engineering Chemistry Research

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Modeling the Dynamic Viscosity of Ionic Solutions

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