Heat and Mass Transfer Analysis of an unsteady Non-Newtonian Magnetohydrodynamic Fluid Flow (Semi-Analytical Solution)-Reference-Cited by-同舟云学术

Heat and Mass Transfer Analysis of an unsteady Non-Newtonian Magnetohydrodynamic Fluid Flow (Semi-Analytical Solution)

Published:2023-12-31 Issue: Volume:18 Page:182-194
ISSN:2224-3461
Container-title:WSEAS TRANSACTIONS ON HEAT AND MASS TRANSFER
language:en
Short-container-title:1790-5044

Author:

El Harfouf Amine¹,Herbazi Rachid²,Mounir Sanaa Hayani¹,Mes-Adi Hassane³,Wakif Abderrahim⁴

Affiliation:

1. Multidisciplinary Laboratory of Research and Innovation (LaMRI), Energy, Materials, Atomic and Information Fusion (EMAFI) Team, Polydisciplinary Faculty of Khouribga, Sultan Moulay Slimane University, MOROCCO

2. Intelligent Systems and Applications Laboratory (LSIA), EMSI, Tangier, MOROCCO

3. Laboratory of Process Engineering, Computer Science and Mathematics, National School of Applied Sciences of the Khouribga University of Sultan Moulay Slimane, MOROCCO

4. Faculty of Sciences Aïn Chock, Laboratory of Mechanics, Hassan II University, Casablanca, MOROCCO

Abstract

In the presence of a time-dependent chemical reaction, this work investigates unsteady squeezing Casson nanofluid flow and heat transfer between two parallel plates under the influence of a uniform magnetic field. Considering the effects of viscosity dissipation, heat generation from friction resulting from flow shear, Brownian motion, Joule heating, and thermodiffusion. The problem's nonlinear differential equations are solved using the Runge–Kutta (RK-4) technique and the Homotopy Perturbation technique. The excellent accuracy of the results is evident since they have been compared with other results from earlier research. In the form of graphs and tables, flow behavior under the many physical factors that are modified is also covered and well described. This work has shown that, by normalizing flow behavior, magnetic fields may be utilized to manage a variety of flows. Additionally, it is demonstrated that in every situation, the effects of positive and negative squeeze numbers on heat and mass transfer flow are opposite. Moreover, the thermophoresis parameter decreases as the concentration field increases. However, when the Brownian motion parameter is increased, the concentration profile gets better. Additionally, several other significant factors were examined. The results of this study can facilitate quicker and easier research and assist engineers.

Publisher

World Scientific and Engineering Academy and Society (WSEAS)

Subject

General Physics and Astronomy

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