Influence of Hall and Slip on MHD Reiner-Rivlin blood flow through a porous medium in a cylindrical tube

The current study aims to scrutinize the peristalsis of magnetohydrodynamics Reiner-Rivlin fluid model in a cylindrical tube through porous medium. The basic equations, including momentum, heat, and concentration are tackled in the valuable presence of Hall current, Joule heating, viscous-dissipatio...

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Bibliographic Details
Published in:Soft computing (Berlin, Germany) Germany), 2024-02, Vol.28 (4), p.2799-2810
Main Authors: Yasin, M., Hina, S., Naz, R.
Format: Article
Language:English
Subjects:
Algebraic
Analytical Methods in Soft Computing
Approximation
Artificial Intelligence
Blood flow
Boundary conditions
Chemical reactions
Computational Intelligence
Control
Darcy number
Electromagnetism
Engineering
Exact solutions
Fluid flow
Foundation
Heat
Investigations
Magnetic fields
Magnetohydrodynamics
Mathematical Logic and Foundations
Mathematical models
Mechatronics
Non-Newtonian fluids
Ohmic dissipation
Parameters
Perturbation methods
Physiology
Porous media
Resistance heating
Reynolds number
Robotics
Slip
Veins & arteries
Velocity
Velocity distribution
Viscosity
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Summary:The current study aims to scrutinize the peristalsis of magnetohydrodynamics Reiner-Rivlin fluid model in a cylindrical tube through porous medium. The basic equations, including momentum, heat, and concentration are tackled in the valuable presence of Hall current, Joule heating, viscous-dissipation, and Soret effects. Moreover, slip effect is also entertained. The considered system is simplified by approximating with long wavelengths and very low Reynolds numbers. Perturbation technique is chosen to obtain the closed form analytical solutions. The impact of influential parameters is presented through plots and physically discussed in detail. The main conclusions of this work are that the velocity and temperature fields exhibit opposite behavior for the Hartman number and Hall parameter. The slip parameter has minimizing impact on velocity distribution. The fluid velocity tends to increase when Reiner-Rivlin fluid parameter is incremented. The Darcy number has upgrading impact on fluid temperature. The solute concentration minifies when slip parameter is incremented. It can be visualized that size of trapped bolus becomes larger on increasing the value of Hall and slip parameter. This research investigation basically examine the blood flow through an artery under strong electric and magnetic field effects. Therefore, this study laid the ground work for scientists, engineers, and medical practitioners working in physiological field.
ISSN:1432-7643
1433-7479
DOI:10.1007/s00500-023-09538-2