Time-dependent model of mixed electroosmotic/pressure-driven three immiscible fluids in a rectangular microchannel
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Author(s)
Haiwang, Li
Wong, Teck Neng
Nguyen, Nam-Trung
Griffith University Author(s)
Year published
2010
Metadata
Show full item recordAbstract
The time-dependent aspects of pressure-driven three-liquid flow under the effect of electroosmotic flow (EOF) are analytically studied, in which non-conducting liquid is delivered by the pressure gradient and the interfacial viscous forces of two conducting liquids, the two conducting liquids are driven by electroosmosis and pressure gradient. The flow of the three liquids depends on the coupling effects between them, which involve the electrokinetic effect. The surface charges at the liquid-liquid interface are accounted in this model. At the interface, the shear stress is not continuous because of the presence of the surface ...
View more >The time-dependent aspects of pressure-driven three-liquid flow under the effect of electroosmotic flow (EOF) are analytically studied, in which non-conducting liquid is delivered by the pressure gradient and the interfacial viscous forces of two conducting liquids, the two conducting liquids are driven by electroosmosis and pressure gradient. The flow of the three liquids depends on the coupling effects between them, which involve the electrokinetic effect. The surface charges at the liquid-liquid interface are accounted in this model. At the interface, the shear stress is not continuous because of the presence of the surface charges. With Laplace transform method, an analytical solution of such time-dependent three-liquid flow in rectangular channel is presented.
View less >
View more >The time-dependent aspects of pressure-driven three-liquid flow under the effect of electroosmotic flow (EOF) are analytically studied, in which non-conducting liquid is delivered by the pressure gradient and the interfacial viscous forces of two conducting liquids, the two conducting liquids are driven by electroosmosis and pressure gradient. The flow of the three liquids depends on the coupling effects between them, which involve the electrokinetic effect. The surface charges at the liquid-liquid interface are accounted in this model. At the interface, the shear stress is not continuous because of the presence of the surface charges. With Laplace transform method, an analytical solution of such time-dependent three-liquid flow in rectangular channel is presented.
View less >
Journal Title
International journal of heat and mass transfer
Volume
53
Issue
4
Copyright Statement
© 2010 Elsevier Inc. This is the author-manuscript version of this paper. Reproduced in accordance with the copyright policy of the publisher. Please refer to the journal's website for access to the definitive, published version.
Subject
Mathematical sciences
Physical sciences
Engineering
Engineering practice and education not elsewhere classified