Electrokinetic Effect of a Two-Liquid Interface within a Slit Microchannel

This paper presents an investigation of the electrokinetic effect at a two-liquid (immiscible liquid-aqueous solution) interface within a slit microchannel using a three-dimensional (3D) numerical model, with a particular focus on the impact of the surface zeta-potential and liquid phase height on the interface electrokinetic velocity. The findings indicate that the direction of the interface movement depends on the zeta-potentials at the two-liquid interface and the microchannel wall. When the absolute value of the negative zeta-potential at the interface is smaller than that at the wall, the interface moves toward the negative pole of the applied direct current (DC) electric field; conversely, it moves in the opposite direction. The velocity of interface motion decreases as the height of the aqueous phase and the dynamic viscosity ratio between the immiscible liquid and the aqueous solution increase. Conversely, the velocity increases with an elevation in the height of the immiscible liquid phase and the DC electric field intensity. This study holds significant importance in elucidating the patterns of change in fluid interface electrokinetic effects and their potential applications in manipulating and separating particulate pollutants within water systems.

Automated summary

This paper investigates the electrokinetic effect at a two-liquid interface within a microchannel and explores the influence of surface zeta-potential and liquid phase height on the interface velocity. The results demonstrate that the direction and velocity of interface movement are determined by the zeta-potentials and height differences between the two liquids and the microchannel. This study has significant importance in understanding and manipulating fluid interface electrokinetic effects.