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MHD Mixed Convection Nanofluid Flow over Convectively Heated Nonlinear due to an Extending Surface with Soret Effect

Jamel Bouslimi, M. A. Abdelhafez, A. M. Abd-Alla, S. M. Abo‐Dahab, Khaled H. Mahmoud

2021Complexity22 citationsDOIOpen Access PDF

Abstract

The aim of this paper is to investigate the flow of MHD mixed convection nanofluid flow under nonlinear heated due to an extending surface. The transfer of heat in nanofluid subject to a magnetic field and boundary conditions of convective is studied to obtain the physical meaning of the convection phenomenon. The governing partial differential equations (PDEs) of the boundary layer are reduced to ordinary differential equations (ODEs) considering a technique of the transformation of similarity. The transformed equations are solved numerically considering the technique of an efficient numerical shooting applying the Runge–Kutta technique scheme from the fourth‐fifth order. The results corresponding to the dimensionless speed, temperature, concentration profiles, and the Nusselt number reduced, and the Sherwood numbers are presented by figures to display the physical meaning of the phenomena. A comparison has been made between the obtained results with the previous results obtained by others and agrees with them if the new parameters vanish. The results obtained indicate the impacts of the nondimensional governing parameters, namely, magnetic field parameter M , Soret number Sr, heat source λ , thermal buoyancy parameter λ T , and solutal buoyancy parameter λ C on the flow, temperature, and concentration profiles being discussed and presented graphically.

Topics & Concepts

NanofluidNusselt numberSherwood numberCombined forced and natural convectionFlow (mathematics)MagnetohydrodynamicsBuoyancyThermodynamicsMechanicsLewis numberPartial differential equationConvectionPhysicsMagnetic fieldMathematicsHeat transferNatural convectionMass transferMathematical analysisReynolds numberTurbulenceQuantum mechanicsNanofluid Flow and Heat TransferHeat Transfer MechanismsFluid Dynamics and Turbulent Flows