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Numerical study of linear and nonlinear stability in double-diffusive Hadley-Prats flow through a horizontal porous layer with Soret and internal heat source effects

Rafeek, M; Reddy, G. Janardhana; Matta, Anjanna; Basha, Hussain; Anwar Bég, O

Authors

M Rafeek

G. Janardhana Reddy

Anjanna Matta

Hussain Basha

O Anwar Bég



Contributors

Abstract

Numerical analysis is constructed to study the onset of double-diffusion convection mechanism through an infinite parallel permeable channel with heat generation, mass flow and Soret impacts. Homogenous isotropic Darcy's flow model is deployed to elucidate the porous features. The roll instabilities pertaining to longitudinal and transverse cases are examined through linear and nonlinear stability analysis. The unit-less eigenvalue problem is constructed through linear and nonlinear stability assumptions and which is solved numerically using a fourth order Runge-Kutta scheme. The critical values of wave and thermal Rayleigh parameters are evaluated. Extended graphical and tabular visualization is presented to describe the onset of convection mechanism. The results of this semi-numerical investigation may be useful in environmental, geothermal and chemical engineering processes. In addition, the critical í µí± í µí± § value is also determined for a range of thermo-physical numbers. Significant modifications in the flow patterns are computed with mass flow parameter and vertical thermal and solutal Rayleigh number. With an increment in Soret (thermo-diffusive) parameter í µí±†í µí±Ÿ the regime 2 become more unstable. Based on the nonlinear stability analysis, an elevation in solutal Rayleigh number also induces earlier instability. The collective influence of Lewis number and horizontal concentration parameter is observed to render the system more stable.

Citation

Rafeek, M., Reddy, G. J., Matta, A., Basha, H., & Anwar Bég, O. (in press). Numerical study of linear and nonlinear stability in double-diffusive Hadley-Prats flow through a horizontal porous layer with Soret and internal heat source effects. Numerical Heat Transfer, Part B Fundamentals, 1-24. https://doi.org/10.1080/10407790.2024.2316841

Journal Article Type Article
Acceptance Date Feb 5, 2024
Online Publication Date Feb 29, 2024
Deposit Date Feb 9, 2024
Publicly Available Date Mar 1, 2025
Journal Numerical Heat Transfer, Part B: Fundamentals
Print ISSN 1040-7790
Publisher Taylor and Francis
Peer Reviewed Peer Reviewed
Pages 1-24
DOI https://doi.org/10.1080/10407790.2024.2316841
Keywords Computer Science Applications, Mechanics of Materials, Condensed Matter Physics, Modeling and Simulation, Numerical Analysis