Behavior of Non-Newtonian Nano-Williamson Fluid Flow Over a Stretching Sheet Filled by Porous Medium: Multiple Slips and Magnetic Field Effects

The intention of this investigation research work is to study Multiple slip (Velocity slip & Concentration) effects on two-dimensional, steady, electrically conducting, incompressible, laminar, viscous, Williamson-nanofluid flow through a porous medium towards a stretching sheet in the presence of magnetic field and chemical reaction is investigated numerically. In this work,  similarity transformations are used to derive a set of non-linear partial differential equations governing the flow. The resultant dimensionless ordinary differential equations which are linear  are solved numerically by Runge-Kutta method along with shooting technique. In this work, the profiles for velocity, concentration, and temperature are studied by variations of physical parameters graphically. Also the numerical values of heat and mass transfer rates and skin-friction coefficients are presented in tabular forms with variations of above same parameters. Based on these plots and values the conclusions are given, and the obtained results are tested for their accuracy.