Abstract
The study aims to investigate the effect of magneto-hydrodynamic on a non-Newtonian unsteady blood flow with internal heat energy in the presence of blood ironic properties characterized by stenosis. The formulated mathematical equations resulted in differential forms and were solved analytically by Differential Transform Method. The obtained solutions were displayed by graphs showing different flow physiognomies like blood velocity, temperature profile, Nusselt number, wall shear stress and stream function.
The results indicated that velocity profile increases as magnetic field, Darcy number and aneurysmal artery rise, while it decreases as heat radiation, Reynold number, and Casson parameter speedup. The temperature profile increases as magnetic field, and Reynold number rise.
Furthermore, wall shear stress increases as heat radiation increases but drops as Reynold number accelerates. This happens due to the fact that magnetic field on blood flow increases the viscosity of the blood flow that bring rise in the Lorentz force and Reynolds number indicates the significant dominance of viscous forces over inertial forces, which keeps the flow in the laminar path.
Recommended Citation
Joseph, Babatunde A.; Sunday, Dada M.; Funsho, Bello A.J.; Disu, Akeem B.; F., Alamu-Awoniran; and Y., Danas James
(2024).
(R2111) Effect of Stenotic-Aneurysmal Arterial Regime on Unsteady Magnetohydrodynamic Non-Newtonian Blood Flow with Heat Radiation,
Applications and Applied Mathematics: An International Journal (AAM), Vol. 20,
Iss.
1, Article 14.
Available at:
https://digitalcommons.pvamu.edu/aam/vol20/iss1/14