Fluid flow problems with convective boundary conditions have applications in the science and engineering worlds. Specifically, they are relevant in the heating and cooling processes observed in glass fiber production, and aerodynamic extrusion. This paper investigates the problem of steady MHD double-diffusive, viscous dissipative boundary layer flow over a vertical plate with heat source, reacting species, and thermal and mass transfer gradients effects. Usually, the problem of flow through porous media is examined using the Boussinesq’s approximations. The governing nonlinear partial differential equations are coupled and complex. Making them tractable, they are linearized into a set of ordinary differential equations using the similarity transform. The evolving set of ordinary differential equations is solved numerically using the fifth-order Runge-Kutta Fehlberg Method and Maple 21 mathematical computational software. The results obtained for the concentration, temperature, and velocity are presented graphically. The analysis of results shows, amongst others, that an increase in the magnetic field parameter increases the temperature and concentration, but decreases the velocity of the fluid; an increase in the Biot number increases the temperature, concentration, and velocity of the fluid; an increases in the concentration difference parameter increases the temperature, but decreases the concentration and velocity of the fluid; an increase in the Eckert number increases the concentration, but decreases the temperature and velocity of the fluid.
Published in | International Journal of Fluid Mechanics & Thermal Sciences (Volume 9, Issue 1) |
DOI | 10.11648/j.ijfmts.20230901.11 |
Page(s) | 1-11 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2023. Published by Science Publishing Group |
Double-Diffusion, Heat Source, MHD, Reacting Species, Thermal/Mass Transfer Gradients, Viscous Dissipation
[1] | Aziz A., 2009. A similarity solution for a laminar thermal boundary layer over a flat plate with a convective surface boundary condition. Comm. Nonlinear Sci. Numer. Simulat., 14, 1064-1068. |
[2] | Ajadi S. O., Adegoke A., Aziz A., 2009. Slip boundary layer flow of a non-Newtonian fluid over a vertical plate with convective thermal boundary condition. Int. J. Nonlinear Sci., 8 (3), 300-306. |
[3] | Makinde O. D., 2010a. Similarity solution of hydro-magnetic heat and mass transfer over a vertical plate with a convective surface boundary condition. Int. J. Phy. Sci. 5 (6), 700-710. |
[4] | Makinde O. D., 2010b. On MHD heat and mass transfer over a moving vertical plate with a convective surface boundary condition. Canadian J. Chem. Eng. 88 (6), 983-990. |
[5] | Makinde D. O., Olarewaju P. O., 2010. Buoyancy effects on thermal boundary layer flow over a vertical plate with a convective boundary condition. J. Fluids Eng. 132/044501-1. |
[6] | Makinde O. D., 2011a. Similarity solution for natural convection for a moving vertical plate with internal heat generation and a convective boundary condition. Thermal Sci. 15 (1), S137-S143. |
[7] | Makinde O. D., 2011b. MHD mixed-convection interaction with thermal radiation and nth order chemical reaction past a vertical porous plate embedded in a porous medium. Chem. Eng. Comm. 198 (4), 590-608. |
[8] | Gangadhar K., Reddy N. B., Kameswaran P. K., 2012. Similarity solution of hydro-magnetic heat and mass transfer over a vertical plate with convective surface boundary condition and chemical reaction. Int. J. Nonlinear Sci. 3 (3), 298-307. |
[9] | Rout B. R., Parida S. K., Panda, S., 2013. MHD heat and mass transfer of chemically reacting fluid flow over a vertical plate in presence of a heat source with convective boundary condition. Int. J. Chem. Eng. 1-10. |
[10] | Abbasi M., Navah G. H., Petroudi I. R., 2014. Analytic solution of hydrodynamic and thermal boundary layers flow over a vertical plate in a uniform stream of fluid with convective surface boundary condition. Indian J. Sci. Res. 1 (2), 241-247. |
[11] | Emmanuel Arthur, E. M., Seine I. Y, Seidu A., 2014. On chemically reacting hydro-dynamic flow over a flat plate in the presence of radiation with viscous dissipation and convective boundary conditions. American J. Appl. Math., 2 (3), 179-185. |
[12] | Etwire C. J., Seini Y. I., 2014. Radiative MHD flow over a vertical plate with convective boundary condition. American J. Appl. Math. 2 (6), 214-220. https://doi:10.11648/j.ajam.20140206.14 |
[13] | Imoro R., Arthur F. M., Seini Y. I., 2014. Heat and mass transfer over a vertical surface with convective boundary conditions in the presence of viscous dissipation and nth-order chemical reaction. Int. J. Comput. and Appl. Math. 9 (2), 101-118. |
[14] | Shateyi S., 2017. Heat and mass transfer for natural convection MHD flow over a permeable moving vertical plate with convective boundary condition in the presence of viscous dissipation. AIP Conf. Proc., 1863, 560075, https://doi.org/10.5098/hmt.9.7. |
[15] | Hossain M. A., Takhar H. S., 1996. Radiation effect on mixed convection along with a vertical plate with uniform surface temperature. Heat Mass Transf., 31, 243-348. |
[16] | Rahman M. M., Sattar M. A., 2006. The magneto-hydrodynamic convective flow of a micropolar fluid past a continuously moving vertical porous plate in the presence of heat generation/absorption. J. Heat Transf., 128 (2), 142-152. |
[17] | Ibrahim F. S., Elaiw A. M., Bakr A. A., 2008. Effect of the chemical reaction and radiation absorption on the unsteady MHD free convection flow past a semi-infinite vertical permeable moving plate with heat source and suction. Comm. in Nonlinear Sci. and Numer. Simul. 13 (6), 1056-1066. |
[18] | Rajeswari R., Jothiram B., Nelson V. K., 2009. Chemical reaction, heat, and mass transfer on non-linear MHD boundary layer flow through a vertical porous surface in the presence of suction. Appl. Math. Sci., 3 (49-52), 2469-2480. |
[19] | Makinde O. D., Ogulu A., 2009. The effect of thermal radiation on the heat and mass transfer flow of a variable viscosity fluid past a vertical porous plate permeated by a transverse magnetic field. Chem. Eng. Comm., 195 (12), 1575-1584. |
[20] | Mohammed R. A., Abo-Dahab S. M., 2009. Influence of chemical reaction and thermal radiation on the heat and mass transfer in MHD micropolar flow over a vertical moving porous plate in a porous medium with heat generation. Int. J. Therm. Sci. 48 (9), 1800-1813. http://dx.doi.org/10.1016/j.ijthermalsci.2009.01.019. |
[21] | Makinde D. O., Ogulu A., 2010. The effects of thermal radiation on the heat and mass transfer flow of a variable viscosity fluid flow past a vertical porous plate permeated by a transverse magnetic field. Chem. Eng. Comm. 195 (12), 1575-1584. |
[22] | Pal D., Talukdar B., 2010. Perturbation analysis of unsteady magneto-hydrodynamic convective heat and mass transfer in a boundary layer slip flow past a vertical permeable plate with thermal radiation and chemical reaction', Comm. Nonlinear Sci. and Numer. Simulat. 15 (7), 1813-1830. |
[23] | Narayana P. V., Kesavaiah D. Ch., Venkataramana S., 2011. Viscous dissipation and thermal radiation effects on unsteady MHD convection flow past a semi-infinite vertical permeable moving porous plate. Int. J. Math. Archives 2 (4), 76. |
[24] | Parida S. K., Acharya M., Dash G. C., Panda S., 2011. MHD heat and mass transfer in a rotating system with periodic suction. Arabian J. Sci. and Eng., 36 (6), 1139-1151. |
[25] | Rajput U. S., Kumar S., 2012. Radiation effects on MHD flow past an impulsively started vertical plate with variable heat and mass transfer. Int. J. Appl. Math. and Mechs. 8, 66-85. |
[26] | Yazdt M. E., Moradi A., Dinavand S., 2013. Radiation effects on MHD stagnation point flow of a Nanofluid. Res. J. Appl. Sci., Eng. and Tech., 5 (22), 5201-5208. |
[27] | Khan M. S., Wahiduzzaman M., Karim I., Islam M. S., Alam, M. M., 2014. Heat generation effects on unsteady mixed convection flow from a vertical porous plate with an induced magnetic field. Procedia Eng. 90, 238-244. http://dx.doi.org/10.1016/j.proeng.2014.11.843. |
[28] | Devi R. L. V. R., Neeraja A., Reddy N. B., 2016. Effects of radiation on unsteady MHD mixed convection flow past an accelerating vertical porous plate with suction and chemical reaction. Int. J. Technic. Res. Applic., 4 (2), 1. |
[29] | Umamaheswar M., Raju M. C., Varma S. V. K., Gireeshkumar J., 2016. Numerical investigation of MHD free convection flow of a non-Newtonian fluid past an impulsively started vertical plate in the presence of thermal diffusion and radiation absorption. Alexandria Eng. J., 55, 2005-2014. https://doi.org/10.1016/j.aej.2006.07.014 |
[30] | Okuyade W. I. A., Abbey T. M., Gima-Laabel A. T., 2018. Unsteady MHD free convective chemically reacting fluid flow over a vertical plate with thermal radiation, Dufour, Soret, and constant suction effects. Alexandria J. Eng., 57, 3863-3871. Doi: 10.1016/j.aej.2018.02.006. |
[31] | Othman M., Mahdy A. M. S., 2018. Numerical studies for solving free convective boundary layer flow over a vertical plate, Mechs. and Mech. Eng., 22 (1), 41-48. |
[32] | Kharabela S., Sampada K. P., Gouranga C. D., 2019. Higher order chemical reaction on MHD Nanofluid flow with slip boundary conditions: a numerical approach. Math. Modeling of Eng. Problems. 6 (2), 293-299. |
[33] | Okuyade W. I. A., Okor, T., 2019a. Transient MHD free convective chemically reacting flow over a moving hot vertical porous plate with heat generation/absorption, thermal radiation, viscous dissipation, oscillating suction, and free stream velocity effects. J. Math. andComputat. Sci., 9 (6), 739-754. Doi: 1.2891/jmcs/4079. |
[34] | Okuyade W. I. A., Okor T., 2019b. Unsteady MHD free convective chemically reacting flow over a vertical plate with a heat source, thermal radiation, and oscillating wall temperature, concentration, and suction effects. American J. Fluid Dyn., 9 (2), 33-47 Doi: 10.5923/j.ajfd.20190902.01. |
[35] | Incropera F. P., De-Witt D. P., 1981. Fundamentals of Heat Transfer, John Wiley, and Sons, New York. |
APA Style
Okuyade Ighoroje Wilson Ata, Mebine Promise. (2023). MHD Double-Diffusive and Viscous Dissipative Boundary Layer Flow over a Vertical Plate with Heat Source, Reacting Species, and Thermal and Mass Transfer Gradients. International Journal of Fluid Mechanics & Thermal Sciences, 9(1), 1-11. https://doi.org/10.11648/j.ijfmts.20230901.11
ACS Style
Okuyade Ighoroje Wilson Ata; Mebine Promise. MHD Double-Diffusive and Viscous Dissipative Boundary Layer Flow over a Vertical Plate with Heat Source, Reacting Species, and Thermal and Mass Transfer Gradients. Int. J. Fluid Mech. Therm. Sci. 2023, 9(1), 1-11. doi: 10.11648/j.ijfmts.20230901.11
AMA Style
Okuyade Ighoroje Wilson Ata, Mebine Promise. MHD Double-Diffusive and Viscous Dissipative Boundary Layer Flow over a Vertical Plate with Heat Source, Reacting Species, and Thermal and Mass Transfer Gradients. Int J Fluid Mech Therm Sci. 2023;9(1):1-11. doi: 10.11648/j.ijfmts.20230901.11
@article{10.11648/j.ijfmts.20230901.11, author = {Okuyade Ighoroje Wilson Ata and Mebine Promise}, title = {MHD Double-Diffusive and Viscous Dissipative Boundary Layer Flow over a Vertical Plate with Heat Source, Reacting Species, and Thermal and Mass Transfer Gradients}, journal = {International Journal of Fluid Mechanics & Thermal Sciences}, volume = {9}, number = {1}, pages = {1-11}, doi = {10.11648/j.ijfmts.20230901.11}, url = {https://doi.org/10.11648/j.ijfmts.20230901.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijfmts.20230901.11}, abstract = {Fluid flow problems with convective boundary conditions have applications in the science and engineering worlds. Specifically, they are relevant in the heating and cooling processes observed in glass fiber production, and aerodynamic extrusion. This paper investigates the problem of steady MHD double-diffusive, viscous dissipative boundary layer flow over a vertical plate with heat source, reacting species, and thermal and mass transfer gradients effects. Usually, the problem of flow through porous media is examined using the Boussinesq’s approximations. The governing nonlinear partial differential equations are coupled and complex. Making them tractable, they are linearized into a set of ordinary differential equations using the similarity transform. The evolving set of ordinary differential equations is solved numerically using the fifth-order Runge-Kutta Fehlberg Method and Maple 21 mathematical computational software. The results obtained for the concentration, temperature, and velocity are presented graphically. The analysis of results shows, amongst others, that an increase in the magnetic field parameter increases the temperature and concentration, but decreases the velocity of the fluid; an increase in the Biot number increases the temperature, concentration, and velocity of the fluid; an increases in the concentration difference parameter increases the temperature, but decreases the concentration and velocity of the fluid; an increase in the Eckert number increases the concentration, but decreases the temperature and velocity of the fluid.}, year = {2023} }
TY - JOUR T1 - MHD Double-Diffusive and Viscous Dissipative Boundary Layer Flow over a Vertical Plate with Heat Source, Reacting Species, and Thermal and Mass Transfer Gradients AU - Okuyade Ighoroje Wilson Ata AU - Mebine Promise Y1 - 2023/06/15 PY - 2023 N1 - https://doi.org/10.11648/j.ijfmts.20230901.11 DO - 10.11648/j.ijfmts.20230901.11 T2 - International Journal of Fluid Mechanics & Thermal Sciences JF - International Journal of Fluid Mechanics & Thermal Sciences JO - International Journal of Fluid Mechanics & Thermal Sciences SP - 1 EP - 11 PB - Science Publishing Group SN - 2469-8113 UR - https://doi.org/10.11648/j.ijfmts.20230901.11 AB - Fluid flow problems with convective boundary conditions have applications in the science and engineering worlds. Specifically, they are relevant in the heating and cooling processes observed in glass fiber production, and aerodynamic extrusion. This paper investigates the problem of steady MHD double-diffusive, viscous dissipative boundary layer flow over a vertical plate with heat source, reacting species, and thermal and mass transfer gradients effects. Usually, the problem of flow through porous media is examined using the Boussinesq’s approximations. The governing nonlinear partial differential equations are coupled and complex. Making them tractable, they are linearized into a set of ordinary differential equations using the similarity transform. The evolving set of ordinary differential equations is solved numerically using the fifth-order Runge-Kutta Fehlberg Method and Maple 21 mathematical computational software. The results obtained for the concentration, temperature, and velocity are presented graphically. The analysis of results shows, amongst others, that an increase in the magnetic field parameter increases the temperature and concentration, but decreases the velocity of the fluid; an increase in the Biot number increases the temperature, concentration, and velocity of the fluid; an increases in the concentration difference parameter increases the temperature, but decreases the concentration and velocity of the fluid; an increase in the Eckert number increases the concentration, but decreases the temperature and velocity of the fluid. VL - 9 IS - 1 ER -