Electromagnetic and non-Darcian effects on a micropolar non-Newtonian fluid boundary-layer flow with heat and mass transfer
Ouaf, Mahmoud; Abou-zeid, MY;
Abstract
The purpose of this paper is to investogate the ectromagnetic and micropolar properties on biviscosity fluid flow with heat and mass transfer through a non-Darcy porous medium. Morever, The heat source, viscous dissipation, thermal diffusion and chemical reaction are taken into consideration. The system of non linear equations which govern the motion is transformed into ordinary differential equations by using a suitable similarity transformations. These equations are solved by making use of Rung-Kutta-Merson method in a shooting and matching technique. The numerical solutions of the velocity, microtation velocity, temperature and concentration are obtained as a functions of the physical parameters of the problem. Moreover the effects of these parameters on these solutions are discussed numerically and depicted graphically. It is found that the microtation velocity increases or deceases as the electric parameter, Hartman parameter and the microrotation parameter increase. Morever, the temperature increases as Forschheimer number, Eckert number increase.
Other data
Title | Electromagnetic and non-Darcian effects on a micropolar non-Newtonian fluid boundary-layer flow with heat and mass transfer | Authors | Ouaf, Mahmoud ; Abou-zeid, MY | Keywords | SLIP;Micro-polar fluid;heat and mass transfer;electromagnetic flow;non-Darcy porous medium;HOMOTOPY PERTURBATION METHOD;MHD PERISTALTIC FLOW;THERMAL-RADIATION;POROUS-MEDIUM;STRETCHING SHEET;NANOFLUID FLOW | Issue Date | 2021 | Publisher | IOS PRESS | Journal | INTERNATIONAL JOURNAL OF APPLIED ELECTROMAGNETICS AND MECHANICS | ISSN | 1383-5416 | DOI | 10.3233/JAE-201623 | Scopus ID | 2-s2.0-85112867179 | Web of science ID | WOS:000685124400009 |
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