Double layer electrical conductivity as a stability criterion for concentrated colloidal suspensions

Double layer electrical conductivity as a stability criterion for concentrated colloidal suspensions

[Display omitted] •Relationship between particle electrical conductivity and DLVO colloidal stability.•Identified processing window for the stability control of concentrated suspensions.•DLVO secondary attractive minimum lies at 1.5 kT for the equilibrium conductivity.•At the minimum reversible dist...

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Bibliographic Details
Published in:Colloids and surfaces. A, Physicochemical and engineering aspects Vol. 520; pp. 9 - 16
Main Authors: Cruz, Robinson C.D., Segadães, Ana M., Oberacker, Rainer, Hoffmann, Michael J.
Format: Journal Article
Language:English
Published: Elsevier B.V 05-05-2017
Subjects:
Alumina
Colloidal interactions
DLVO
Electrokinetics
Particle conductivity
DLVO
Colloidal interactions
Alumina
Particle conductivity
Electrokinetics
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Summary:[Display omitted] •Relationship between particle electrical conductivity and DLVO colloidal stability.•Identified processing window for the stability control of concentrated suspensions.•DLVO secondary attractive minimum lies at 1.5 kT for the equilibrium conductivity.•At the minimum reversible distance (∼7nm) particles conductivity is zero.•More accurate measurement of static ζ–potential at the isoconductivity point. The slightly attractive inter–particle equilibrium potential associated with electrostatically stabilized suspensions of minimum viscosity is described by the DLVO theory and commonly gauged by static ζ-potential measurements, plagued with experimental uncertainties. In this work, the electrokinetic mobility of alumina particles was measured in suspensions prepared with selected solids content and ionic strength, as well as was the electrical conductivity of each suspension and suspending liquid. Particles electrical conductivity was then calculated and related to the colloidal stability described by the DLVO theory, enabling the identification of a processing window for the stability control of concentrated suspensions. The maximum repulsive potential and distance between particles (∼46nm) corresponds to the particles maximum conductivity. When the particles conductivity is zero, the diffuse layer is fully collapsed and they stand at the minimum reversible distance (∼7nm). At the equilibrium conductivity, a potential curve is produced with a secondary attractive minimum of ∼1.5 kT at an inter–particle distance of ∼17nm, as suggested by the DLVO theory and the Equipartition of Energy theorem. The condition for accurate measurement of static ζ-potential occurs at the isoconductivity point between particles and suspending liquid.
ISSN:0927-7757
1873-4359
DOI:10.1016/j.colsurfa.2017.01.059