Electroosmosis modulated peristaltic biorheological flow through an asymmetric microchannel: mathematical model
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Publication Details
Author list: Tripathi D, Jhorar R, Beg OA, Shaw S
Publisher: Springer Verlag (Germany)
Place: DORDRECHT
Publication year: 2018
Journal: Meccanica (0025-6455)
Journal acronym: MECCANICA
Volume number: 53
Issue number: 8
Start page: 2079
End page: 2090
Number of pages: 12
ISSN: 0025-6455
eISSN: 1572-9648
Languages: English-Great Britain (EN-GB)
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Abstract
A theoretical study is presented of peristaltic hydrodynamics of an aqueous electrolytic non-Newtonian Jeffrey bio-rheological fluid through an asymmetric microchannel under an applied axial electric field. An analytical approach is adopted to obtain the closed form solution for velocity, volumetric flow, pressure difference and stream function. The analysis is also restricted under the low Reynolds number assumption (Stokes flow) and lubrication theory approximations (large wavelength). Small ionic Pecl,t number and Debye-Huckel linearization (i.e. wall zeta potential ae 25 mV) are also considered to simplify the Nernst-Planck and Poisson-Boltzmann equations. Streamline plots are also presented for the different electro-osmotic parameter, varying magnitudes of the electric field (both aiding and opposing cases) and for different values of the ratio of relaxation to retardation time parameter. Comparisons are also included between the Newtonian and general non-Newtonian Jeffrey fluid cases. The results presented here may be of fundamental interest towards designing lab-on-a-chip devices for flow mixing, cell manipulation, micro-scale pumps etc. Trapping is shown to be more sensitive to an electric field (aiding, opposing and neutral) rather than the electro-osmotic parameter and viscoelastic relaxation to retardation ratio parameter. The results may also help towards the design of organ-on-a-chip like devices for better drug design.
Keywords
Analytical approach, Electrokinetic transport, Peristalsis, Trapping, viscoelastic fluids
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