Spectral quasilinear numerical simulation of micropolar convective wall plumes in high permeability porous media


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Abstract

Laminar natural convection plume of a microstructural non-Newtonian fluid along a vertical surface about a line heat source in a saturated high permeability porous medium is studied. The transformed non-linear boundary value problem is solved numerically using a rigorously tested SQLM algorithm, which combines a spectral collocationmethod with the quasilinearization method (QLM). The effects of Grashof number, Prandtl number, Darcy number and Eringen micropolar rheological material parameters are examined. Excellent stability and convergence of the spectral method is demonstrated. Validation of solutions with the Keller box finite difference is included. Applications of the study arise in geological (petroleum) fluid dynamics.

About the authors

O. A. Bég

Fluid Mechanics, Spray Research Group, School of Computing, Science and Engineering, Newton Bldg, G77

Author for correspondence.
Email: O.A.Beg@salford.ac.uk
United Kingdom, England, Manchester, M54WT

S. S. Motsa

School of Mathematical Sciences, Department of Mathematics

Email: O.A.Beg@salford.ac.uk
Swaziland, Kwaluseni

A. Kadir

Spray Research Group, School of Computing, Science and Engineering, Newton Bldg, G79

Email: O.A.Beg@salford.ac.uk
United Kingdom, England, Manchester, M54WT

T. A. Bég

Renewable Energy and Geodynamics Research

Email: O.A.Beg@salford.ac.uk
United Kingdom, Dickenson Rd, England, Manchester, M13

M. N. Islam

Computational Mechanics, Mechanical and Aeronautical Engineering, Department of Engineering and Mathematics

Email: O.A.Beg@salford.ac.uk
United Kingdom, Sheaf Bldg, Sheaf Street, England, Sheffield, S11WB

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