Williamson Fluid Characteristics on Three-Dimensional Steady Nanofluid Flow Past a Bi-Directional Stretching Sheet: Double Diffusion and MHD Effects

The goal of this study is to determine how heat radiation and chemical reactions affect a non-Newtonian Williamson-nanofluid flow across a stretched sheet in a porous media. There will be no compressibility, consistent viscosity, or three-dimensionality to the flow. Applying the finite element approach yields the system's approximate solutions to its partial differential equations. For many important parameter values, the graphical representations of the concentration, velocity, temperature, mass, heat transfer rate, and shear stresses of Williamson nanofluids at the stretched sheet are provided. On top of it, the shear stresses are shown. Finally, the results show that the previous study and the comparison inquiry are very much in accord.