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Comparative numerical study between MHD Forchheimer nano and hybrid nanofluid flows over stretching sheet under aligned magnetic field in the presence of radiation absorption.

Authors :
Venkateswara Raju, K.
Maheswari, Ch.
Mohana Ramana, R.
Vijayakumar Varma, S.
Changal Raju, M.
Source :
International Journal of Modelling & Simulation. Sep2024, p1-18. 18p. 23 Illustrations.
Publication Year :
2024

Abstract

This study investigates the mass and heat transfer properties of Ag-H2O nanofluid MHD Forchheimer flows and Ag-MoS2/H2O hybrid nanofluid over two-dimensional linear stretching surfaces in aligned magnetic fields with absorption of radiation. The fluid experiences rotational motion around the vertical axis at a consistent angular speed. The system of nonlinear ODEs is derived from the set of nonlinear PDEs by use of similarity transformations. The BVP-5C shooting approach in MATLAB is then employed to solve the associated system of ODEs. As the Forchheimer number, porosity parameter, rotation parameter and aligned magnetic field exhibit an ascent, the velocity profile along the x-axis and y-axis experiences a decrement. Simultaneously, an augmentation in the magnetic parameter, thermal radiation and rotation parameter induces a heightened temperature profile. Additionally, greater values of the Forchheimer number, rotation parameter and magnetic parameters correspond to an increase in concentration profile. Furthermore, the results indicated an increased temperature profile in the Ag-MoS2/H2O hybrid nanofluid compared to that in the Ag-H2O nanofluid for magnetic, rotation and radiation parameters. Also, the concentration profile of magnetic and rotation parameters along with the Forchheimer number were noted to be higher in the Ag-MoS2/H2O hybrid nanofluid compared to that in the Ag-H2O nanofluid. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
02286203
Database :
Academic Search Index
Journal :
International Journal of Modelling & Simulation
Publication Type :
Academic Journal
Accession number :
179682268
Full Text :
https://doi.org/10.1080/02286203.2024.2393306