Effect of chemical absorption on Jeffery Fluid Flow in saturated Porous Media with variable thermal conductivity

Authors

  • Akeem Babatunde Disu National Open University of Nigeria, Nigeria https://orcid.org/0000-0002-8045-7320
  • Emmanuel Omokhuale Federal University Gusau, Nigeria
  • Sulyman Olakunle Salawu Bowen University, Nigeria

DOI:

https://doi.org/10.21580/jnsmr.v10i1.20157

Keywords:

Thermal conductivity, Heat and mass diffusion, Porous medium, Jeffery material, Finite difference method

Abstract

This study investigates the impact of species absorption of Jeffery fluid flow through a saturated permeable medium with variable thermal conductivity. The dimensional partial nonlinear derivative model controlling the chemical reacting fluid flow is transformed to invariant form.  The resulting flow equations are computed numerically using an approximated finite implicit Crack-Nicolson. A chemical absorption of fluid reactant occurs in a boundless vertical device.   Computations are performed for different parameters to examine their sensitivity under isothermal temperature conditions. The computed results are offered graphically for qualitative and quantitative insights into the flow behaviour. The obtained outcomes revealed that the fluid flow rate rises with an increasing values of the parameters and, and it damps with upsurge in the values of the parameters,  and. The heat transfer field is reduced with enhancing values of the thermal source, viscous dissipation and time, but declines for a boosted value of the terms suction and Prandtl number. Also, the mass transfer field is higher when mass absorption and time are increased, and diminish with an elevate in the values of Schmidt number and chemical reactions.

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Author Biography

Akeem Babatunde Disu, National Open University of Nigeria

Department of Mathematics, National Open University of Nigeria, Jabi, Abuja, Nigeria.

Senior Lecturer

References

Ahmed, N., Gaswami, J. K., & Barua, D. P. (2013). Effects of chemical reaction and radiation on an unsteady MHD flow past an accelerated infinite vertical plate with variable temperature and mass transfer. Indian Journal of Pure and Applied Mathematics, 44(4), 443 – 466.

Altine, M. M., Omokhaule, O., Onwubuya, I. O. & Disu A. B. (2020). Heat absorption effect on free convection flow past vertical porous pipe with mass transfer. International Journal of Science for Global Sustainability, 6(1), 94-100.

Anjalidevi, S. P. & Kandasamy, R. (2000). Effects of chemical reaction heat and mass transfer on MHD flow past aa semi-infinite plate. Z. Angew. Mathematics and Mechanics, 80, 697-701.

Dada, M. S. & Adefolaju, F. H. (2012). Dissipation, MHD and radiation effects on an unsteady convective heat and mass transfer in a Darcy-Forchheimer porous medium. Journal of Mathematics Research, 4(2), 110 – 127.

Das, U. N., Deka, R. K. & Soundalgekar, V. M. (1994). Effects of mass Transfer on flow past an impulsively stated infinite vertical plate with constant heat flux and chemical reaction. Forsch. Ingenieurwes, 60, 284 – 287.

Disu, A. B. & Dada M. S. (2018). Effects of variable thermal conductivity on radiative MHD flow in a porous medium between two vertical wavy walls. Scientia Africana: An International Journal of Pure and Applied Sciences Volume 17(1), 89 -102

Disu, A. B. & Omokhuale E. (2022). Effects of injection and Heat sink/source on convective Kuvshink fluid through a porous medium. Communication in Physical Sciences, 8(2), 145-157.

Disu, A. B. & Salawu, S. 0. (2023). Thermal distribution of magneto-tangent hyperbolic flowing fluid over a porous sheet: A lie-group analysis. Journal of Nigerian Society of Physical Sciences 5(2023)1103.

Hassan, A.R., Salawu, S .O., Disu, A. B. & Aderele, O. R., (2022). Thermodynamic analysis of a tangent hyperbolic hydromagnetic heat generating fluid in quadratic Boussinesq approximation. Journal of Computational Mathematics and Data Science, 4, 100058.

Hayat, T., Muhammad, T., Saleh, A. & Liao, S. (2016). Darcy-Forchhiemer flow with variable thermal conductivity and catta-neo-christov heat flux. International Journal of Numerical Methods for Heat Fluid Flow, 28(8):2355 – 2369.

Hayat, T., Shah, F., Hussain, Z. & Alseadi, A. (2018). Darcy Forchheimer flow of Jeffery Nanofluid with heat generation/absorption and melting heat transfer. Thermal Science, 23, 314-314.

Idowu, A. S., Dada, M. S., and Jimoh, A. (2013). Heat and mass transfer of magnetohydrodynamics (Mhd) and dissipative fluid flow past a vertical moving plate with variable suction. Mathematics Theory and Modelling, 3(3), 80 – 102.

Lavanya, B. and Ratman, A. L. (2014). Dufour and Soret effects on steady MHD free convective flow past a vertical porous plate embedded in a porous medium with chemical reaction, radiation, heat generation and viscous dissipation. Advances in Applied Science Research, 5(1), 127 – 142.

Kandasamy, R., Periasamy, K. & Sivagnana Prabhu, K. K. (2005). Effects of chemical reactions heat and mass transfer along a wedge with heat source in the presence of suction/injection. International Journal of Heat Mass Transfer, 48, 1388 – 1393.

Khan, M. I., Hayat, T. & Alsaedi, A. (2017). Numerical analysis for Darcy-Forchhiemer flow in presence of homogeneous-heterogeneous reactions, Results in Physics, 7, 2644-2650.

Muthucumaraswamy, R. & Ganesan, P. (2001). First order chemical reaction on flow past an impulsively stated vertical plate with uniform heat and mass flux. Acta Mehanica, 147, 45 – 57.

Ojemen G., Disu A. B. & Omokhauale E. (2019). Combination effects of radiative heat source and magnetic field on a free convective flow in moving vertical plate filled with porous material. Caliphate Journal of Science and Technology, 2(1), 135-140.

Olanrewaju, P. O. & Gbadeyan, J. A. (2011). Effects of Soret, Dufour and chemical reaction, thermal radiation and volumetric heat generation/absorption on mixed convection stagnation point flow on an isothermal vertical plate in a porous media. Pacific Journal of Science and Technology, 12(2), 234 – 245.

Postelnicu, A. (2007). Influence of chemical reaction on heat and mass transfer by natural Convection from vertical surfaces in a porous media considering Soret and Dufour effects. Heat and Mass Transfer, 43, 595 – 602.

Rajashekar, M. N. (2014). Effects of Dufour and Soret on unsteady MHD heat and mass transfer flow past a semi-infinite moving vertical plate in a porous medium with viscous dissipation. International Journal op Applied Physics and Mathematics, 4(2), 130 – 134.

Rao A. S., Nagenda N. & Prasad V. R. (2015). Heat transfer in a non-Newtonian Jeffery’s fluid over non-isothermal wedge. International Conference on Computational Heat and Mass Transfer, 127, 775-782.

Rasool, G., Shafiq, A. & Durur, H. (2021). Darcy-Forchhiemer relation in magnetohydrodynamic Jeffery nanofluid over stretching surface. Discrete and Continuous Dynamical Systems Series S, 14(7), 2497 – 2515.

Sharma, B. K., Yadav, K., Mishra, N. K., & Chaudhary, R. C. (2012). Soret and Dufour effects on unsteady MHD mixed convection flow past a radiative vertical porous plate embedded in a porous medium with chemical reaction. Applied Mathematics, 3, 717- 723.

Shahzad, F., Jamshed, W., Sajid, T., Shamshuddin, M. D., Safdar, R., Salawu, S. O., Eid, M.R., Hafeez, M. B. & Krawczuk, M. (2022). Electromagnetic control and dynamics of generalized Burgers nanoliquid flow containing motile microorganisms with Cattaneo-Christov relations: Galerkin finite element mechanism. Applied Sciences, 12(17), 8636.

Salawu, S.O., Obalalu, A. M. & Shamshuddin, M. D. (2022). Nonlinear solar thermal radiation efficiency and energy optimization for magnetized hybrid Prandtl-Eyring nanoliquid in aircraft. Arabian Journal for Science and engineering, 22, 070801.

Sharma, B. K., Yadav, K., Mishra, N. K. & Chaudhary, R. C. (2012). Soret and Dufour effects on unsteady MHD mixed convection flow past a radiative vertical porous plate embedded in a porous medium with chemical reaction. Applied Mathematics, 3, 717- 723.

Shateyi, S. and Motsa, S. (2011). Unsteady Magnetohydrodynamics convective heat and mass transfer past an infinite vertical plate in a porous medium with thermal radiation, heat generation/absorption and chemical reaction. Advance Topics in Mass Transfer, 7, 145 – 162.

Uwanta. I. J. & Omokhuale, E. (2014). Effects of variable thermal conductivity on heat and mass transfer with Jeffery fluid. International Journal of Mathematical Archive, 5(3). 135 – 149.

Vedarathi, N., Dharmaiah, G., Venkatadri, K. & Gaffar, S. A. (2021). Numerical Study of radiative non-darcy nanofluid flow over a stretching sheet with a convective conditions and energy activation. Nonlinear Engineering, 10: 159 – 176.

Zhang R., Zaydan M., Alshehri M., Raju C.S.K., Wakif A. & Shah N. A. (2023). Further insights into mixed convective boundary layer flows of internally heating Jeffrey nano-fluids: Stefan’s blowing case study with connective heating and thermal radiation. Case Study in Thermal Engineering, 104121.

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Published

2024-07-31

Issue

Vol. 10 No. 1 (2024): June

Section

Original Research Articles

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