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Electrical MHD flow via stretching sheet with Arrhenius activation energy utilizing modified Buongiorno model: the optimization


Citation

Norzawary, N. H.A. and Bakar, S. A. and Pop, I. and Wahid, N. S. and Arifin, N. M. and Bachok, N. (2025) Electrical MHD flow via stretching sheet with Arrhenius activation energy utilizing modified Buongiorno model: the optimization. Malaysian Journal of Mathematical Sciences, 19 (3). pp. 1035-1062. ISSN 1823-8343

Abstract

This research highlights a comprehensive mathematical model of Arrhenius activation energy and viscous dissipation impacts on electrically conductive magnetohydrodynamic (MHD) flow via shrinking sheet. The model utilizes a modified Buongiorno approach, which implies nano fluid dynamics factors such as thermophoresis and Brownian motion. In general description, electrical MHD describes fluid flow such as plasma or liquid metals that influenced by electric and magnetic fields. The Arrhenius activation energy effect then introduces a temperature-dependent reaction rate that typically modelled by an exponential function, considering its ability in increasing reaction rates as temperature rises. The mathematical derivation of this study involves a transformation of partial differential equations converting to ordinary differential equations, subjected to their respective boundary conditions, through a similarity transformation to simplifies complex interactions into a solvable framework. These equations are numerically solved employing bvp4c function in MATLAB to observe precise analysis of flow behaviour and heat transfer properties. The study conclude that the magnetic parameter and Brownian motion parameter reduce heat transfer, while the activation energy and temperature difference parameters amplify concentration profiles. The inclusion of the electric field parameter is shown to elevate the boundary layer flow and heat transfer rate. Based on the heat transfer analysis, an optimization by Response Surface Methodology (RSM) further analyses these solutions to identify an optimal combination of three critical parameters in order to maximize heat transfer rate. This optimization provides insights in efficient thermal management applications and supports advancements in cooling or energy sustainability.


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Additional Metadata

Item Type: Article
Subject: Mathematics (all)
Divisions: Faculty of Science
Institute for Mathematical Research
DOI Number: https://doi.org/10.47836/mjms.19.3.14
Publisher: Universiti Putra Malaysia
Keywords: Arrhenius activation energy; Electrical MHD; Modified buongiorno model; Response surface methodology; Stretching
Sustainable Development Goals (SDGs): SDG 9: Industry, Innovation and Infrastructure, SDG 7: Affordable and Clean Energy, SDG 4: Quality Education
Depositing User: MS. HADIZAH NORDIN
Date Deposited: 23 Jun 2026 04:56
Last Modified: 23 Jun 2026 04:56
Altmetrics: http://www.altmetric.com/details.php?domain=psasir.upm.edu.my&doi=10.47836/mjms.19.3.14
URI: http://psasir.upm.edu.my/id/eprint/126241
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