Influence of Hall current and Joule heating on entropy generation during electrokinetically induced thermoradiative transport of nanofluids in a porous microchannel

A comprehensive theoretical study of entropy generation during electrokinetically driven transport of a nanofluid is of prime concern in the paper. The flow is considered to take place on a wavy channel under the action of an external transverse magnetic field and an external pressure gradient. Navi...

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Bibliographic Details
Published in:Applied mathematics and mechanics 2019-10, Vol.40 (10), p.1509-1530
Main Authors: Mallick, B., Misra, J. C., Chowdhury, A. R.
Format: Article
Language:English
Subjects:
Applications of Mathematics
Blood flow
Capillaries
Chemotherapy
Classical Mechanics
Computational fluid dynamics
Cooling effects
Electrokinetics
Electromagnetism
Entropy
External pressure
Ferromagnetism
Fluid flow
Fluid- and Aerodynamics
Hall effect
Magnetic fields
Mathematical analysis
Mathematical Modeling and Industrial Mathematics
Mathematics
Mathematics and Statistics
Microchannels
Nanofluids
Nanoparticles
Ohmic dissipation
Partial Differential Equations
Resistance heating
Streaming potential
Temperature distribution
Thermal radiation
Transport
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Summary:A comprehensive theoretical study of entropy generation during electrokinetically driven transport of a nanofluid is of prime concern in the paper. The flow is considered to take place on a wavy channel under the action of an external transverse magnetic field and an external pressure gradient. Navier slips at the walls of the channel and thermal radiation have been taken into account in the study. The theoretical study has been carried out by developing a mathematical model by taking into account the effects of Joule heating, viscous dissipation, and the transverse magnetic field on heat transfer during the electrokinetic transport of the fluid. The derived analytical expressions have been computed numerically by considering the nanofluid as a mixture of blood and ferromagnetic nanoparticles. Variations in velocity, streaming potential, temperature distribution, Nusselt number, and Bejan number associated with the electrokinetic flow in capillaries have been investigated by the parametric variation method. The results have been presented graphically. The present investigation reveals that streaming potential decreases due to the Hall effect, while for the cooling capacity of the microsystem, we find an opposite behavior due to the Hall effect. The study further reveals that the fluidic temperature is reduced due to increase in the Hall current, and thereby thermal irreversibility of the system is reduced significantly. The results presented here can be considered as the approximate estimates of blood flow dynamics in capillaries during chemotherapy in cancer treatment.
ISSN:0253-4827
1573-2754
DOI:10.1007/s10483-019-2528-7