Please use this identifier to cite or link to this item: http://hdl.handle.net/123456789/3429
Title: Effectiveness of Radiation on Magneto-Combined Convective Boundary Layer Flow in Polar Nanofluid around a Spherical Shape
Authors: Swalmeh M.Z. 
Shatat F. 
Alwawi F.A. 
Ibrahim M.A.H. 
Sulaiman I.M. 
Yaseen N. 
Naser M.F.M. 
Keywords: convection boundary layer floW;Heat transfer;magnetic field
Issue Date: 2022
Publisher: MDPI
Journal: Fractal and Fractional 
Abstract: 
Many physical aspects emerging from the local structure and micromotions of liquid particles can be studied by utilizing the governing model of micropolar liquid. It has the ability to explain the behavior of a wide range of real fluids, including polymeric solutions, liquid crystals, lubricants, and animal blood. This earned it a major role in the treatment of many industrial and engineering applications. Radiative heat transmission induced by a combined convection flow of micropolar fluid over a solid sphere, and its enhancement via nanoparticle oxides, are investigated in this study. An applied magnetic field and a constant wall temperature are also considered. The Tiwari–Das model is used to construct the mathematical model. An approximate numerical solution is included using the Keller box method, in which its numerical calculations are performed via MATLAB software, to obtain numerical results and graphic outputs reflecting the effects of critical parameters on the physical quantities associated with heat transfer. The investigation results point out that a weakness in the intensity of the magnetic field, or an increment in the nanoparticle volume fraction, causes an increment in velocity. Raising the radiation parameter promotes energy transport, angular velocity, and velocity.
Description: 
Web of Science / Scopus
URI: http://hdl.handle.net/123456789/3429
ISSN: 25043110
DOI: 10.3390/fractalfract6070383
Appears in Collections:Faculty of Entrepreneurship and Business - Journal (Scopus/WOS)

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