Specific ion effects: Interaction between nanoparticles in electrolyte solutions

V. Deniz; M. Boström; D. Bratko; F. W. Tavares; B. W. Ninham

doi:10.1016/j.colsurfa.2007.08.020

Specific ion effects: Interaction between nanoparticles in electrolyte solutions

V. Deniz, M. Boström, D. Bratko, F. W. Tavares^*, B. W. Ninham

^*Corresponding author for this work

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

17 Citations (Scopus)

Abstract

Dependence of colloidal interactions on salt identity, observed frequently in experiments, can be accounted for once ion specific non-electrostatic forces are included in the theory. Ability to predict the effect of added salt on the phase diagram of colloid dispersions is essential for the design of processes involving nanocolloids. The Ornstein-Zernike equation with hypernetted chain closure approximation provides a viable first estimate for the potential of mean force between ionized nanoparticles like alumina aggregates in aqueous electrolytes subject to dispersion interactions with hydrated simple ions. Calculated potentials of mean force enable the prediction of osmotic second virial coefficients and phase diagrams showing a dramatic dependence on ion type. The choice of salt therefore provides an efficient, non-intrusive way to tune the phase behavior of nanoparticle dispersions.

Original language	English
Pages (from-to)	98-102
Number of pages	5
Journal	Colloids and Surfaces A: Physicochemical and Engineering Aspects
Volume	319
Issue number	1-3
DOIs	https://doi.org/10.1016/j.colsurfa.2007.08.020
Publication status	Published - 15 Apr 2008

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title = "Specific ion effects: Interaction between nanoparticles in electrolyte solutions",

abstract = "Dependence of colloidal interactions on salt identity, observed frequently in experiments, can be accounted for once ion specific non-electrostatic forces are included in the theory. Ability to predict the effect of added salt on the phase diagram of colloid dispersions is essential for the design of processes involving nanocolloids. The Ornstein-Zernike equation with hypernetted chain closure approximation provides a viable first estimate for the potential of mean force between ionized nanoparticles like alumina aggregates in aqueous electrolytes subject to dispersion interactions with hydrated simple ions. Calculated potentials of mean force enable the prediction of osmotic second virial coefficients and phase diagrams showing a dramatic dependence on ion type. The choice of salt therefore provides an efficient, non-intrusive way to tune the phase behavior of nanoparticle dispersions.",

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AU - Deniz, V.

AU - Boström, M.

AU - Bratko, D.

AU - Tavares, F. W.

AU - Ninham, B. W.

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AB - Dependence of colloidal interactions on salt identity, observed frequently in experiments, can be accounted for once ion specific non-electrostatic forces are included in the theory. Ability to predict the effect of added salt on the phase diagram of colloid dispersions is essential for the design of processes involving nanocolloids. The Ornstein-Zernike equation with hypernetted chain closure approximation provides a viable first estimate for the potential of mean force between ionized nanoparticles like alumina aggregates in aqueous electrolytes subject to dispersion interactions with hydrated simple ions. Calculated potentials of mean force enable the prediction of osmotic second virial coefficients and phase diagrams showing a dramatic dependence on ion type. The choice of salt therefore provides an efficient, non-intrusive way to tune the phase behavior of nanoparticle dispersions.

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KW - Ionic dispersion potentials

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KW - OZ-HNC integral equation

KW - Phase diagram

KW - Polarizability

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Specific ion effects: Interaction between nanoparticles in electrolyte solutions

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