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Activation Energy Performance through Magnetized Hybrid Fe3O4–PP Nanofluids Flow with Impact of the Cluster Interfacial Nanolayer

M. Zubair Akbar Qureshi, Qadeer Raza, Aroosa Ramzan, Muhammad Faisal, Bagh Ali, Nehad Ali Shah, Wajaree Weera

2022Mathematics17 citationsDOIOpen Access PDF

Abstract

The current work investigated the mass and heat transfer of the MHD hybrid nanofluid flow subject to the impact of activation energy and cluster interfacial nanolayer. The heat transport processes related to the interfacial nanolayer between nanoparticles and base fluids enhanced the base fluid’s thermal conductivity. The tiny particles of Fe3O4 and PPy were considered due to the extraordinary thermal conductivity which is of remarkable significance in nanotechnology, electronic devices, and modern shaped heat exchangers. Using the similarity approach, the governing higher-order nonlinear coupled partial differential equation was reduced to a system of ordinary differential equations (ODEs). Fe3O4–PPy hybrid nanoparticles have a considerable influence on thermal performance, and when compared to non-interfacial nanolayer thermal conductivity, the interfacial nanolayer thermal conductivity model produced substantial findings. The increase in nanolayer thickness from level 1 to level 5 had a significant influence on thermal performance improvement. Further, the heat and mass transfer rate was enhanced with higher input values of interfacial nanolayer thickness.

Topics & Concepts

NanofluidMaterials scienceThermal conductivityHeat transferHeat exchangerCluster (spacecraft)NanoparticleThermodynamicsNanotechnologyComposite materialPhysicsComputer scienceProgramming languageNanofluid Flow and Heat TransferHeat Transfer and OptimizationHeat Transfer Mechanisms
Activation Energy Performance through Magnetized Hybrid Fe3O4–PP Nanofluids Flow with Impact of the Cluster Interfacial Nanolayer | Litcius