Induced-charge nonlinear electrokinetic phenomena and applications in micro/nano fluidics
Induced-charge nonlinear electrokinetic phenomena have drawn increasing attention not only due to their fundamental importance but also due to their potential applications for manipulating fluid flows and particles in microfluidics. Such type of nonlinear electrokinetic phenomena is jointly driven b...
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Format: | Theses and Dissertations |
Language: | English |
Published: |
2012
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Online Access: | https://hdl.handle.net/10356/50865 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | Induced-charge nonlinear electrokinetic phenomena have drawn increasing attention not only due to their fundamental importance but also due to their potential applications for manipulating fluid flows and particles in microfluidics. Such type of nonlinear electrokinetic phenomena is jointly driven by the external electric field and the surface charge induced by the same field on polarizable or conducting surfaces, and is also frequently referred to as induced-charge electrokinetic phenomena. The fluid or particle velocity generated by induced-charge electrokinetics is proportional to the square of the external electric field strength. This is strikingly different from the conventional linear electrokinetics for which the fluid or particle velocity is linearly proportional to the external electric field strength. As a result, the induced-charge electrokinetics can generate larger flow rates and even allows for net flows under AC driving electric fields. Based on the basic theories of electrokinetics and electrostatics, effective electric boundary conditions between liquid-solid interfaces are derived for induced-charge electrokinetics under two situations. These boundary conditions are capable of predicting the induced zeta potentials over surfaces of solids with finite electric properties which are crucial for theoretical characterization of induced-charge electrokinetics. The applications of these two types of boundary conditions are demonstrated by analyzing the DC field driven induced-charge electroosmosis in a slit microchannel embedded with a pair of dielectric blocks and the AC field driven induced-charge electroosmosis around a leaky-dielectric cylinder, respectively. The calculations show that the basic flow patterns for induced-charge electroosmosis are the flow vortices which get stronger as the polarizability and /or the conductivity of solids increase. A complete numerical model is then developed to describe dynamic characteristics of the charging of electric double layer and the associated flows around polarizable dielectrics. The presented model does not invoke various assumptions that can be easily violated in practical applications but usually are made in existing analyses. The comparison with a benchmark solution ensures the validity of the complete model. It is shown that the complete model corroborates the two time scales during the EDL charging revealed in former asymptotic analyses. More importantly, the detailed information inside the EDL during the transient charging is resolved for the first time, which provides insight into the induced-charge electrokinetic phenomena with finite thickness of EDLs. Furthermore, the concept of induced‐charge electrokinetics is extended to nanofluidics. Two nanofluidic systems, i.e., a straight nanochannel and a tapered nanochannel, are proposed for flexible modulations of both ionic transport and fluid flow. For the straight channel, the modulations are achieved by th control
of gate voltage (i.e., the voltage applied on the conducting walls of nanochannel). For the tapered channel, the modulations are achieved by varying the direction
and magnitude of external electric field and the taper angel of the channel walls.
Both systems are advantageous over other nanofluidic systems driven by the
conventional linear electrokinetics which usually exhibit poor control of both ionic transport and fluid flow. Finally, a novel method relying on induced‐charge electrokinetics is
developed for particle trapping. The proposed technique has been demonstrated experimentally for high‐throughput trapping and concentration of particles
ranging from submicron to several microns. In addition, a theoretical model is
formulated to explain the experimental observations and the trapping mechanisms. |
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