1993
DOI: 10.1063/1.465108
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The interpretation of dielectric response measurements on colloidal dispersions using the dynamic Stern layer model

Abstract: Articles you may be interested inDynamic and dielectric response of charged colloids in electrolyte solutions to external electric fields Sound speed dispersion measurements and their interpretation in the presence of a shallow buried layer.The standard description of electrokinetic phenomena deals with a particle whose charge is uniformly smeared over its surface and considers ion transport only within a Gouy-Chapman diffuse layer. Experimental studies with colloidal dispersions have shown that this model is … Show more

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Cited by 99 publications
(102 citation statements)
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“…More recently, Kijlstra et al (12) applied the theory of Stern layer transport to the study of the low-frequency dielectric response of colloidal suspensions, extending the thin double-layer theory of Fixman (3, 7). Likewise, Rosen et al (13) generalized the standard theory of the conductivity and dielectric response of a colloidal suspension in AC fields of DeLacey and White (5), assuming the model of Stern layer developed by Zukoski and Saville. Mangelsdorf and White (14, 15) also developed a general dynamic Stern layer model to be applied to electrophoresis and dielectric response in oscillating electric fields.…”
Section: Extension To Include a Dynamic Stern Layermentioning
confidence: 99%
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“…More recently, Kijlstra et al (12) applied the theory of Stern layer transport to the study of the low-frequency dielectric response of colloidal suspensions, extending the thin double-layer theory of Fixman (3, 7). Likewise, Rosen et al (13) generalized the standard theory of the conductivity and dielectric response of a colloidal suspension in AC fields of DeLacey and White (5), assuming the model of Stern layer developed by Zukoski and Saville. Mangelsdorf and White (14, 15) also developed a general dynamic Stern layer model to be applied to electrophoresis and dielectric response in oscillating electric fields.…”
Section: Extension To Include a Dynamic Stern Layermentioning
confidence: 99%
“…suspensions (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15). However, in a great number of practical situations, suspensions are usually more concentrated than those typically considered as dilute, so some theoretical approaches to the issue of concentrated suspensions, including electrophoresis (16), sedimentation (17,18), electrical conductivity (19), and electroacoustic phenomena (20)(21)(22), to mention just a few, have been published in the past few decades.…”
Section: Introductionmentioning
confidence: 99%
“…Rosen et al [1993] considered in their model the possible exchange of counterions between the Stern layer and the diffuse layer, while Schwarz [1962] considered that the counterions of the entire electrical double layer can only move tangentially along the mineral surface. However, the kinetics of the sorption/desorption of the counterions is a slow process, and we believe that this effect can be neglected at the frequencies typically considered for induced polarization (generally above 1 mHz).…”
Section: Appendix A: Generalization To a Distribution Of Polarizationmentioning
confidence: 99%
“…[62] For such a lognormal distribution of polarization length scales, the related distribution of the relaxation times is given by [Revil and Florsch, 2010] Schwarz, 1962;Schurr, 1964] or numerically [Rosen et al, 1993]. Rosen et al [1993] considered in their model the possible exchange of counterions between the Stern layer and the diffuse layer, while Schwarz [1962] considered that the counterions of the entire electrical double layer can only move tangentially along the mineral surface.…”
Section: Appendix A: Generalization To a Distribution Of Polarizationmentioning
confidence: 99%
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