Mixed Convection Flow of a Viscous Dissipative and Heat Generating/Absorbing Fluid Through a Slit Microchannel.

Publication Date: 23/10/2024

DOI: 10.52589/AJMSS-LA7BTCRZ


Author(s): Godwin Ojemeri , A. S. Ibrahim, I. O. Onwubuya.

Volume/Issue: Volume 7 , Issue 4 (2024)



Abstract:

This paper is aimed at investigating the consequences of viscous dissipation and super-hydrophobicity on a magnetized mixed convection flow of an electrically conducting fluid across an up facing microchannel influenced by a transverse magnetic field. The plates were alternatively heated and incorporated with heat source/sink effect. The modeled governing equations have been obtained using a semi-analytical (regular perturbation) method. Various line graphs have been plotted to demonstrate the behavior of key parameter dictating the flow. It is found out that the thermal gradient and fluid velocity are significantly enhanced for mounting values of mixed convection , Brickman number , Darcy porous number and heat source parameters in the superhydrophobic microchannel for constant pressure gradient . On the other hand, the velocity deteriorates for increasing levels of magnetic field and heat sink factors. Further, the comparison of this present analysis with previously published literature for limiting cases when and showcased an excellent concurrence, thereby confirming the accuracy and validity of this present investigation. The findings from this research will find relevance in engineering, technological and industrial processes such as for solar collectors, nuclear reactors cooled during emergency shutdown, Nuclear power plants, gas turbines and the various propulsion devices for aircraft, missiles, satellites and space vehicles.


Keywords:

Viscous dissipative fluid, Heat source/sink, Magnetohydrodynamics (MHD), Superhydrophobic surface (SHS), Slit Microchannel.


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CC BY-NC-ND 4.0