Characteristic Analysis of Soret and Corolis Forces on a Natural Convection in a Finite Cavity with Isotropic and Anisotropic Permeable Media
Authors
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Department of Mathematics, New Horizon College of Engineering, Bangalore – 560103, Karnataka ,IN
Sudhir Patel -
Department of Mathematics, Ramaiah Institute of Technology, Bangalore – 560054, Karnataka ,INP. A. Dinesh
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Department of Mathematics, Cambridge Institute of Technology, Bangalore – 560036, Karnataka ,INS. P. Sushma
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Department of Mathematics, Nitte Meenakshi Institute of Technology, Bangalore – 560 064, Karnataka ,INT. C. Sushma
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Department of Mathematics, B. M. S College of Engineering, Bangalore – 560 019, Karnataka ,INM. S. Gayathri
DOI:
https://doi.org/10.18311/jmmf/2023/41762Keywords:
Anisotropic Porous Media, Coriolis force, Isotropic, Natural Convection, Soret Effect.Abstract
Using 3D transmission in a definite cavity with anisotropic and isotropic permeable media rotating at a fixed rotational velocity, the Rayleigh-Benard issue for a viscous, unstable, laminar, incompressible fluid heated from below a horizontal layer is extended in this paper's research. Seven controlling PDEs from the given physical configuration are similarly transformed to produce a system of non-dimensional ODEs. The Rayleigh, Taylor, and Prandtl numbers are examined for their impacts on temperature gradient and velocity in both isotropic and anisotropic conditions using the Fourier series approach. It has been discussed and determined that the results of the stream function and isotherms on a variety of factors are good.
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