On electro-osmotic flows through microchannel junctions

We study the electro-osmotic flow through a T-junction of microchannels whose dielectric walls are weakly polarizable. The present global analysis thus extends earlier studies in the literature concerning the local flow of an unbounded electrolyte solution around nearly insulated wedges. The velocit...

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Bibliographic Details
Published inPhysics of fluids (1994) Vol. 18; no. 11; pp. 117108 - 117108-9
Main Authors Yossifon, G., Frankel, I., Miloh, T.
Format Journal Article
LanguageEnglish
Published Melville, NY American Institute of Physics 01.11.2006
Subjects
Applied fluid mechanics
Exact sciences and technology
Fluid dynamics
Fluidics
Fundamental areas of phenomenology (including applications)
Physics
Streamlines
Pipe flow
Electroosmosis
Vortices
Theoretical study
Hydrodynamics
Branching pipe
Microstructure
T shape
Microfluidics
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Summary:We study the electro-osmotic flow through a T-junction of microchannels whose dielectric walls are weakly polarizable. The present global analysis thus extends earlier studies in the literature concerning the local flow of an unbounded electrolyte solution around nearly insulated wedges. The velocity field is obtained via superposition of an irrotational part associated with the equilibrium zeta potential and the induced-charge electro-osmotic flow originating from the interaction of the externally applied electric field and the charge cloud it induces owing to field leakage through the polarizable dielectric channel walls. Along the channel walls the latter component gives rise to fluid velocities converging toward the corner which dominate the flow in its immediate vicinity. Recent experimental observations in the literature regarding the appearance and subsequent expansion of flow reversal and vortices downstream (initially) and upstream (subsequently) of the junction, are both rationalized in terms of the growing relative importance of this induced contribution to the global velocity field with increasing intensity of the externally applied electric field.
ISSN:1070-6631
1089-7666
DOI:10.1063/1.2391701