Journal of Computational Applied Mechanics

Akbari-Ganji Homotopy Perturbation Method for Analyzing the Pulsatile Blood Flow in Tapered Stenosis Arteries under the Effect of Magnetic Field together with the Impact of Mass and Heat Transfer

Document Type : Research Paper

Authors

Department of Mathematics, College of Education for Pure Science, Basrah University, Basrah, Iraq

Abstract

The two-dimensional pulsatile blood flow in tapered stenosis arteries under the effect of a Magnetic field with mass and heat transfer was analyzed by using a new analytical method called the Akbari-Ganji homotopy perturbation method (AGHPM).This technique is based on integrating the Akbari-Ganji and the homotopy perturbation methods. We succeeded in developing the mathematical model studied by researchers Liu and Liu by adding the effect of the magnetic field of blood flow in addition to the effect of mass and heat transfer on it, this developed model has not been studied before. In the two states (absence and presence) of a magnetic field; the axial velocity, the wall shear stress, flow resistance and volumetric flow rate were investigated under the impact of the angle of tapering, the Grashof number, the solutal Grashof number and magnetic field. The results show that in the case of the absence magnetic field there is good agreement with the previous study made by the researchers Liu and Liu, while in the case of the presence magnetic field it is noted that when the magnetic field increases from 2 to 6, the velocity and flow rate decrease, but in contrast the wall shear stress and resistance flow increases. Moreover, the results establish that AGHPM is effective and extremely accurate in determining the analytical approximate solution for pulsatile blood flow in tapered stenosis arteries under magnetic field influence. Furthermore, the graphs of this novel solution demonstrate the validity, usefulness, and substantiality of AGHPM, and are consistent with the results of earlier investigations.

Keywords

Main Subjects

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Journal of Computational Applied Mechanics
Volume 53, Issue 4
December 2022
Pages 543-570
  • Receive Date: 08 September 2022
  • Revise Date: 04 October 2022
  • Accept Date: 05 October 2022