Hall and ion‐slip effects on mixed convection flow of Williamson nanofluid over a nonlinear porous stretching sheet with variable thermal conductivity

Ibrahim, Wubshet; Anbessa, Temesgen

doi:10.1002/htj.22141

Cited by 9 publications

(1 citation statement)

References 42 publications

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“…The work done by Hang and Qiang (10) , Patil et al (11) and Shobha et al (12) are the good literature for the study of mixed convection through channels. Ibrahim and Anbessa (13) looked into the Williamson nano fluid flow along stretching sheet and results shows that enhancement in Williamson parameter leads to decelerate the fluid temperature. An analysis is made by Cimpean and Pop (14) to investigate the both free and forced flow of nano fluid along a porous filled channel, for the study they considered three nano fluid namely Al2O3-H2O,TiO2-H2O.Cu-H2O.…”

Section: Introductionmentioning

confidence: 99%

Mixed Convection of Williamson Fluid along an Inclined Porous Microchannel with Chemical Reaction by taking Non-Constant Thermal Conductivity: An Entropy Analysis

Manthesha¹,

Mallikarjun²,

Kavitha³

et al. 2021

IJST

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Objective: Mixed convection of Williamson fluid along an inclined porous microchannel with the influence of first-order chemical reaction is considered. The thermal conductivity kept varying throughout the flow. Boundaries of the channel are maintained with slip and jump conditions. With these conditions in this present article we are aimed to analyse the velocity, heat transfer and entropy generation in the flow. Method: The non-linear equations which govern the flow are tackled utilizing the bvp4c technique which involves the finite difference method and improved by using the Lobatto III formula. Findings: Fluid flow, heat transfer and entropy production analysis are done for the various estimations of the parameters which are affecting the flow, and the study highlights that non constant thermal conductivity and mixed convection parameters have to be maintained at lower values for the efficient energy transfer in the model. Entropy production shows the dual trend for distinct estimations of Weinsenberg number. Applications: The obtained result in the present study helps industries to analyse the efficient energy transfer in their engineering designs and thermal equipment's. Also the flow of non-Newtonian fluid has applications in the field of blood flow, lubrication and in many engineering devices such as micro heat exchangers, micro mixers, micro cooling systems.

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