Computational Analysis of MHD Mixed Convection Jeffrey Nanofluid Flow Past a Stretching Sheet With Thermal Radiation
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Keywords:
Jeffrey nano fluid, Mixed convection magnetohydrodynamic, thermal radiation, Brownian and thermophoretic diffusionAbstract
This work considers the effects of thermal radiation, Brownian and thermophoretic diffusion,
and viscous dissipation in the mixed convection magnetohydrodynamic (MHD) flow of a Jeffrey nanofluid
over a nonlinear stretching surface. A set of ordinary differential equations was created from the governing
partial differential equations for momentum, energy, and concentration using the proper similarity
transformations. These nonlinear equations are splved numerically under predetermined boundary
conditions. The results show that increasing the magnetic parameter suppresses the velocity field because
of the increased Lorentz force. Thermal radiation and viscous dissipation enhance the temperature
distribution. The results shed light on a number of industrial procedures, such as viscoelastic nanofluid heat
transfer systems, wire coating, and polymer extrusion.
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