A Comprehensive Analysis of Nanofluid Flow with Mass and Heat Transfer between Parallel Surfaces in a Darcy Porous Medium Considering Chemical Reaction and Thermal Radiation
Khairy, M., Abbas, W., Megahed, A., Emam, M. (2025). A Comprehensive Analysis of Nanofluid Flow with Mass and Heat Transfer between Parallel Surfaces in a Darcy Porous Medium Considering Chemical Reaction and Thermal Radiation. EKB Journal Management System, 184(3), 19-31. doi: 10.21608/erj.2025.378954.1231
Mohamed Khairy; Wael Abbas; Ahmed Megahed; Mohamed Emam. "A Comprehensive Analysis of Nanofluid Flow with Mass and Heat Transfer between Parallel Surfaces in a Darcy Porous Medium Considering Chemical Reaction and Thermal Radiation". EKB Journal Management System, 184, 3, 2025, 19-31. doi: 10.21608/erj.2025.378954.1231
Khairy, M., Abbas, W., Megahed, A., Emam, M. (2025). 'A Comprehensive Analysis of Nanofluid Flow with Mass and Heat Transfer between Parallel Surfaces in a Darcy Porous Medium Considering Chemical Reaction and Thermal Radiation', EKB Journal Management System, 184(3), pp. 19-31. doi: 10.21608/erj.2025.378954.1231
Khairy, M., Abbas, W., Megahed, A., Emam, M. A Comprehensive Analysis of Nanofluid Flow with Mass and Heat Transfer between Parallel Surfaces in a Darcy Porous Medium Considering Chemical Reaction and Thermal Radiation. EKB Journal Management System, 2025; 184(3): 19-31. doi: 10.21608/erj.2025.378954.1231

A Comprehensive Analysis of Nanofluid Flow with Mass and Heat Transfer between Parallel Surfaces in a Darcy Porous Medium Considering Chemical Reaction and Thermal Radiation

Engineering Research Journal
Volume 184, Issue 3, June 2025, Page 19-31  XML PDF (622.52 K)
Document Type: Original Article
DOI: 10.21608/erj.2025.378954.1231
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Authors
Mohamed Khairy1; Wael Abbas email orcid 2; Ahmed Megahed3; Mohamed Emam4
1Arab Academy for Science,Technology and Maritime Transport
2College of Engineering and Technology, Arab Academy for Science, Technology, and Maritime Transport,
3benha university
4helwan university
Abstract
In the last two decades, researchers have focused on the flow of nanofluids between parallel plates due to the growing energy demands and their applications, although much more research is still needed. Therefore, this comprehensive research examines the dynamics of an unsteady Magnetohydrodynamic (MHD) Couette flow of nanofluid through two endlessly parallel porous surfaces was investigated via mass and heat transmit taking into account Chemical Reaction, Heat Generation, and Thermal Radiation under constant pressure gradient. In this study, Water has been proposed as the foundation fluid for copper nanoparticles. The implicit finite difference approach was used to formulate and quantitatively solve the governing partial differential equations. The effects of physical characteristics are graphically presented for varies values during dimensionless speed and temperature profile are considered. The results show that, increase in nanoparticle volume fraction ∅ increase the amount of heat transfer to the nanofluid and hence its temperature increases. The study's findings are applicable to a number of thermal systems, engineering applications, and industrial procedures that use nanofluids for heating and cooling.
Keywords
Unsteady flow; Nanofluid; Couette flow; MHD; Homotopy perturbation method
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