Issue 8, 2022

Effect of charge inversion on nanoconfined flow of multivalent ionic solutions

Abstract

A comprehensive understanding of fluid dynamics of dilute electrolyte solutions in nanoconfinement is essential to develop more efficient nanofluidic devices. In nanoconduits, the electrical double layer can occupy a considerable part of the channel cross-section, therefore the transport properties of a nanoconfined electrolyte solution can be altered by interfacial phenomena such as the charge inversion (CI). CI is an electrokinetic effect that has been associated with the presence of hydrated multivalent cations in nanoconfinement. Here, all-atom molecular dynamics simulations are employed to study the structure and dynamics of aqueous multivalent electrolyte solutions within slit-shaped silica channels. All simulations are conducted for more than 100 ns to capture the equilibrium ion distribution, the interfacial hydrodynamic properties, and to reveal the influence of CI on nanoconfined fluid transport. The electrolyte solutions consist of water as solvent, chloride as co-ion and different counter-ions, i.e., sodium, magnesium and aluminum. We find that the interfacial viscosity is related to the concentration and valence of the counter-ions in the solution. Our results suggest that higher CI is correlated to the presence of a layer of fluid with augmented viscosity adjacent to the channel wall. As the thickness of this interfacial high-viscosity fluid increases, lower flow rates are measured whereas higher interfacial viscosities and friction coefficients are computed.

Graphical abstract: Effect of charge inversion on nanoconfined flow of multivalent ionic solutions

Supplementary files

Article information

Article type
Paper
Submitted
13 May 2021
Accepted
30 Jan 2022
First published
01 Feb 2022

Phys. Chem. Chem. Phys., 2022,24, 4935-4943

Effect of charge inversion on nanoconfined flow of multivalent ionic solutions

A. Rojano, A. Córdoba, J. H. Walther and H. A. Zambrano, Phys. Chem. Chem. Phys., 2022, 24, 4935 DOI: 10.1039/D1CP02102H

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