首页|Analysis of energy transport considering Arrhenius activation energy and chemical reaction in radiative Maxwell nanofluid flow
Analysis of energy transport considering Arrhenius activation energy and chemical reaction in radiative Maxwell nanofluid flow
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NSTL
Elsevier
Nanofluids have innovative possessions that create them hypothetically worthwhile in numerous heat transportation uses, comprising apparatus chilling/vehicle thermal controlling, firewood cells, curative progressions, hybrid-energetic devices, internal freezer and chiller etc. Here the thermo-solutal possessions of convective conditions on nonlinear radiated magnetized Maxwell nanofluid with activation energy in the stagnation region. The homotopic process has been implemented for solutions. The physical parameters are plotted graphically. These outcomes reported that the radiation factor and Prandtl number decline; however, thermophoretic factor intensifies the temperature field of Maxwell nanofluid. Moreover, activation energy factor and mass Biot number exaggerate the concentration field. Additionally, the outcomes for Newtonian case with assessment of former prose are structured in this analysis.
Maxwell nanofluidMagnetic propertiesStagnation point flowNon-linear thermal radiationChemical reactionMAGNETIC-FIELDHEAT-TRANSFERSUBJECTIMPACT
NSTL
Elsevier
