Simulation of thermochemical effects on unsteady magneto hydrodynamics fluids flow in two dimensional nonlinear permeable media

Igba Denen Solomon Igba; Idugba Mathias  Echi; Vezua Emmanuel  Tikyaa

doi:10.46481/asr.2024.3.3.247

Authors

Solomon Denen Igba
[email protected]
Department of Physics, College of Physical Sciences, Joseph Sarwuan Tarkaa University Makurdi, Benue State, Nigeria
Idugba Mathias Echi Department of Physics, College of Physical Sciences, Joseph Sarwuan Tarkaa University Makurdi, Benue State, Nigeria
Emmanuel Vezua Tikyaa Department of Physics, College of Physical Sciences, Joseph Sarwuan Tarkaa University Makurdi, Benue State, Nigeria

Keywords:

MHD fluids flow, Unsteady flow, Magnetic field, Similarity transformation, Heat and mass transfer

Abstract

This study aimed to simulate the thermochemical effects on unsteady magnetohydrodynamic (MHD) fluid flow in a two-dimensional nonlinear permeable medium under the influence of an external space-dependent magnetic field and a non-uniform heat source. Fluid flow is crucial in numerous natural and man-made systems, yet its complexities, especially in MHD contexts, are underexplored. The models momentum, energy, and concentration equations, accounting for the dependence of fluid and media properties, were transformed into nonlinear coupled ordinary differential equations using similarity transformations. These equations were solved numerically using the shooting technique, the sixth-order Runge-Kutta Fehlberg method, and Newton’s Raphson method, supported by Maple software. Computational results were generated for velocity, temperature, and concentration profiles. The skin-friction coefficient, Nusselt Number (which represents heat transfer rate), and Sherwood Number (indicating mass transfer) were also evaluated. The results indicated that velocity increased with the magnetic field parameter, permeability, thermal and mass Grashof Numbers, Prandtl Number, radiation, mass transfer parameters, and wall porosity. Conversely, velocity diminished with an increase in Schmidt Number, space and temperature-dependent heat generation parameters, and unsteadiness. The fluid temperature followed a similar trend, decreasing with increased magnetic field, permeability, Grashof numbers, and other parameters but showed a reverse effect when radiation and unsteadiness were high. Fluid concentration initially increased with smaller parameter values but declined with larger ones. The findings suggested that optimizing thermophysical parameters can significantly enhance heat and mass transfer in unsteady MHD flow through permeable surfaces, making the results relevant for biomedical applications.

Dimensions

REFERENCES

[1] A. Farhad, I. Anees, A. Khan, K. Ilyas, A. Irfan & Badruddin, “Effects of MHD and porosity on entropy generation in two incompressible Newtonian fluids over a thin needle in a parallel free stream”, Scientific Reports 10 (2020) 22305. https://doi.org/10.1038/s41598-020-76125-y.

[2] S. Madhu & R. K. Gaur, “Effect of variable viscosity on chemically reacting magneto-blood flow with heat and mass transfer”, Global Journal of Pure and Applied Mathematics 13 (2017) 26. https://doi.org/10.5890-JAND.2023.03.006.aspx.

[3] J. C. Misra, A. Sinha & G. C. Shit, “A numerical model for magnetohydrodynamic flow of blood in a porous channel”, Journal of Mechanics in Medicine and Biology 11 (2011) 547. https://doi.org/10.1007/s00231-012-1107-6.

[4] L. Shu, “Numerical simulation of groundwater”, Hohai University Lecture Notes, 2020. [Online]. Retrieved from https://www.iahr.org.

[5] D. S. Igba & D. A. Otor, “Simulation of Earth planetary orbits using a modified inverse square model”, International Journal of Recent Innovations in Academic Research 2 (2018) 23. https://zenodo.org/record/131210.

[6] S. Ahmad, M. Farooq, A. Anjum, M. Javed, M. Y. Malik & A. S. Alshomrani, “Diffusive species in MHD squeezed fluid flow through non-Darcy porous medium with viscous dissipation and joule heating”, Journal of Magnetics 23 (2018) 323. https://dspace.kci.go.kr.

[7] A. Sinha, J. C. Misra & G. C. Shit, “Effect of heat transfer on unsteady MHD flow of blood in a permeable vessel in the presence of non-uniform heat source”, Alexandria Engineering Journal 55 (2016) 2023. http://creativecommons.org/licenses/by-nc-nd/4.0/.

[8] B. Zigta, “Effect of thermal radiation and chemical reaction on MHD flow of blood in stretching permeable vessel”, International Journal of Applied Mechanics and Engineering 25 (2020) 198. https://doi.org/10.2478/ijame-2020-0043.

[9] P. R. Sharma & G. Singh, “Effects of variable thermal conductivity, viscous dissipation on steady MHD natural convection flow of low Prandtl fluid on an inclined porous plate with Ohmic heating”, Meccanica 45 (2010) 237. https://doi.org/10.1007/s11012-009-9261-7.

[10] K. M. Joseph, S. Daniel, P. Ayuba & B. G. Agaie, “Effect of chemical reaction on unsteady MHD free convective two immiscible fluids flow”, Science World Journal 12 (2017) 4. https://www.ajol.info/index.php/swj/article/view/166099.

[11] B. Zigta, “Effect of MHD blood flow with velocity, thermal and concentration slip boundary layer”, Engineering and Technology Research 4 (2021) 033. https://doi.org/10.15413/etr.2021.0113.

[12] B. Zigta, “Effect of thermal radiation and chemical reaction on MHD flow of blood in stretching permeable vessel”, International Journal of Applied Mechanics and Engineering 25 (2020) 198. https://doi.org/10.2478/ijame-2020-0043.

[13] A. Subhas, J. V. Tawade & J. N. Shinde, “The effects of MHD flow and heat transfer for the ucm fluid over a stretching surface in presence of thermal radiation”, Hindawi Publishing Corporation Advances in Mathematical Physics 64 (2012) 702681. https://doi.org/10.1155/2012/702681.

[14] P. Sreedivya, R. Y. Sunitha & R. R. Srinivasa, “Performance of nano-casson fluid on convective flow past a permeable stretching sheet: thermophoresis and brownian motion effects”, Journal of Nanofluids 10 (2021) 372. https://doi.org/10.1166/jon.2021.1796.

[15] J. C. Chato, “Heat transfer to blood vessels”, Journal of Biomechanical Engineering 102 (1980) 110. https://doi.org/10.1166/jon.2021.1796.