Electrophoretic Mobility of Colloidal Particles in Weak Electrolyte Solutions

for a swarm of spherical particles applicable for low z poten-A general mobility expression is derived for a swarm of identical tials and all ka values, showing that as ka decreases and/ spherical colloidal particles in concentrated suspensions on the or the particle volume fraction increases (the p

The electrophoretic mobility of a particle covered by a membrane in an a :b electrolyte solution is modeled theoretically. The membrane, which simulates the surface of a biological cell, is ion-penetrable, and carries homogeneously distributed negative fixed charges. An approximate expression for th

for the dynamic mobility of spherical particles which is ap-A theory for the dynamic electrophoretic mobility m of spherical plicable for all ka (k is the Debye-Hu ¨ckel parameter and colloidal particles in concentrated suspensions in an oscillating a is the particle radius) at zero particle permitt

Accurate approximate formulas are obtained for the dynamic electrophoretic mobility of a cylindrical hard colloidal particle in an oscillating electric field for two cases where the cylinder is in a transverse field or in a tangential field. These formulas, expressed in terms of Hankel functions and

In the present paper, we use directly the method of Oh-A general expression for the dynamic electrophoretic mobility shima et al. (9) without decomposing the electrophoresis of a spherical colloidal particle in an oscillating electric field is problem as in Ref. (8) to solve the electrokinetic equat

The analytical theory of the thin double-layer concentration polarization in dilute suspensions of colloidal particles, generalized by the authors to the case of weak electrolyte solutions [C. Grosse and V. N. Shilov, J. Colloid Interface Sci. 211, 160 (1999)], was used to determine the conductivity