Numerical and experimental investigation of the deviation of microparticles inside the microchannel using the vortices caused by the ICEK phenomenon

One field of study in microfluidics is the control, trapping, and separation of microparticles suspended in fluid. Some of its applications are related to cell handling, virus detection, and so on. One of the new methods in this field is using ICEK phenomena and dielectrophoresis forces. In the pres...

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Bibliographic Details
Published in:Electrophoresis 2024-04, Vol.45 (7-8), p.720-734
Main Authors: Ghadamgahi, Seyed Mohammad Ehsan, Shahmardan, Mohammad Mohsen, Nazari, Mohsen, Mansouri, Hamed, Hashemi, Nicole N
Format: Article
Language:English
Subjects:
Deviation
Dielectrophoresis
Fluid flow
Innovations
Microchannels
Microfluidics
Microparticles
Semiconductors
Separation
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Summary:One field of study in microfluidics is the control, trapping, and separation of microparticles suspended in fluid. Some of its applications are related to cell handling, virus detection, and so on. One of the new methods in this field is using ICEK phenomena and dielectrophoresis forces. In the present study, considering the ICEK phenomena, the microparticles inside the fluid are deviated in the desired ratio using a novel ICEK microchip. The deviation is such that after the microparticles reach the floating electrode, they are trapped in the ICEK flow vortex and deviated through a secondary channel that was placed crosswise and noncoplanar above the main channel. For simulation verification, an experimental test is done. The method used for making two noncoplanar channels and separating the particles in the desired ratio with a simple ICEK microchip is an innovation of the present study. Moreover, the adjustment of the percentage of separation of microparticles by adjusting the parameters of the applied voltage and fluid inlet velocity is one of the other innovations of the present experimental study. We observed that for input velocities (150-1200) (µm)/s, respectively, with applied voltages (10-33) V, 100% of the particles can be directed toward the secondary-channel.
ISSN:0173-0835
1522-2683
DOI:10.1002/elps.202300151