Ohmic dissipation impact on flow of Casson-Williamson fluid over a slippery surface through a porous medium

Ohmic dissipation impact on flow of Casson-Williamson fluid over a slippery surface through a porous medium

Through the investigation, in this work, we focused at the steady flow of a Casson-Williamson fluid due to an stretchable, impenetrable sheet with Ohmic dissipation. It is assumed that the impermeable stretched sheet is incorporated into a porous media and has a rough surface. The porous media throu...

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Bibliographic Details
Published in:Indian journal of physics Vol. 97; no. 14; pp. 4277 - 4283
Main Authors: Abbas, W., Megahed, Ahmed M., Ibrahim, M. A., Said, Ahmed A. M.
Format: Journal Article
Language:English
Published: New Delhi Springer India 01-12-2023
Springer Nature B.V
Subjects:
Astrophysics and Astroparticles
Electric fields
Fluid flow
Graphical representations
Heat transfer
Newtonian fluids
Non Newtonian fluids
Nonlinear differential equations
Ohmic dissipation
Ordinary differential equations
Original Paper
Parameters
Physics
Physics and Astronomy
Porous media
Reynolds number
Slip velocity
Steady flow
Temperature profiles
Thermal conductivity
Velocity
Velocity distribution
Ohmic dissipation
Slip velocity
Viscous dissipation
Casson-Williamson fluid
Porous medium
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Summary:Through the investigation, in this work, we focused at the steady flow of a Casson-Williamson fluid due to an stretchable, impenetrable sheet with Ohmic dissipation. It is assumed that the impermeable stretched sheet is incorporated into a porous media and has a rough surface. The porous media through which the non-Newtonian fluid is flowing are supposed to obey Darcy’s law. Magnetic and electric fields’ impacts are considered. We investigate how the process of heat transfer is affected by viscous dissipation and varying thermal conductivity. On the basis of a little magnetic Reynolds number, the controlling basic equations are represented by a system of nonlinear ordinary differential equations. The shooting technique is used to get a numerical solution for this system, which controls both the temperature and velocity fields. Graphical representations of the impact of various parameters on the velocity and temperature profiles are shown. Regarding the significant results, we note that the local electric parameter tends to improve both the velocity and temperature fields, while the porous parameter, Casson parameter and slip velocity parameter decrease the velocity profiles.
ISSN:0973-1458
0974-9845
DOI:10.1007/s12648-023-02754-4