Two Component Non-Darcian Benard Marangoni Convection with Uniform and Non-Uniform Temperature Gradients in a Composite Layer with Variable Heat Sources/Sinks

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Authors

  • Associate Professor, Head of the Department, Department of UG and PG Studies and Research in Mathematics, Government Science College (Autonomous), Nrupatunga University, N.T. Road, Bengaluru-560 001, Karnataka ,IN
  • Research Scholar, Department of UG and PG Studies and Research in Mathematics, Government Science College (Autonomous), Nrupatunga University, N.T. Road, Bengaluru-560 001, Karnataka ,IN
  • Research Scholar, Department of UG and PG Studies and Research in Mathematics, Government Science College (Autonomous), Nrupatunga University, N.T. Road, Bengaluru-560 001, Karnataka ,IN

DOI:

https://doi.org/10.18311/jmmf/2022/31859

Keywords:

Non-Darcy Model, Temperature Dependent Heat Source, Temperature Gradients, Adiabatic Boundaries.

Abstract

In a composite layer that comprises of a porous layer which is sparsely packed and saturated with two component incompressible fluid and above this porous layer lays a layer of the same fluid, with variable heat sources or sinks in both the layers double diffusive non-Darcian Benard Marangoni (DDNBM) convection is investigated. The upper surface of the composite layer has Marangoni effects which depend on temperature and concentration, whereas the lower surface is rigid. The inverted parabolic, parabolic and linear temperature profile is applied to this composite layer, which is surrounded by adiabatic boundaries. The appropriate thermal Marangoni numbers (TMANs) which are the eigen values (EVs) are calculated for all the three temperature gradients. The impact of different parameters on the EVs with respect to depth ratio is examined, thoroughly. The parameters that effect DDNBM convection are found.

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Published

2022-11-02

How to Cite

Sumithra, R., Acharya, D. R., & Archana, M. A. (2022). Two Component Non-Darcian Benard Marangoni Convection with Uniform and Non-Uniform Temperature Gradients in a Composite Layer with Variable Heat Sources/Sinks. Journal of Mines, Metals and Fuels, 70(7A), 112–131. https://doi.org/10.18311/jmmf/2022/31859

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References

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