Joint Effects of Velocity and Thermal Wall Slips on Steady, Laminar, MHD Jeffrey-Nano Fluid Flow Over a Non-Linearly Stretching of a Flat surface

The effect of Thermophoresis and Brownian motion on the time-dependent (steady) magnetohydrodynamic boundary layer Jeffrey fluid flow of a nonlinearly stretching sheet in the existence of nanoparticles is investigated in this research. Non-linear partial differential equations serve as the governing equations in the system. Then, applying appropriate similarity transformations, these equations are reduced into ordinary differential equations. To get numerical solutions to the resulting differential equations, the shooting method is employed. This article presents an in-velocity analysis of a variety of engineering parameters, including the Jeffrey fluid parameter, Brownian motion parameter, Thermophoresis parameter, Stretching sheet parameter, Prandtl number, Lewis number, Velocity slip parameter, and Thermal slip parameter, as well as numerical values for heat and mass transfer. Finally, it is established that the numerical findings are fully compatible with the published results. This kind of scientific study has a variety of applications, including energy conservation, microprocessor cooling, and equipment longevity.