Analytical evaluation of magnetized nanofluid flow in a stagnation point with chemical reaction and nonlinear radiation effect configured by an extended surface

On the account of technological development and engineering applications, the enhancement of thermal energy by introducing nanoparticles is a crucial task in the present era. This present work is to investigate the physical characteristics of a chemical reaction, heat and mass transfer effects on hydrodynamic stagnation point flow of Watlers-B nanoliquid configured by a stretching surface. The effect of fluid viscosity, electrical and thermal conductivity is assumed as temperature function. In addition, the impression of thermal conductivity, Brownian and thermophoretic diffusion are incorporated in the revised model. A theoretical framework is employed to simulate the arisen nonlinear (PDEs). With the assistance of transformations techniques, the contemporary (PDEs) are then diminished to nonlinear system of (ODEs). For nonlinear computations, the resulting equations are programmed in the Mathematica 11.0 programing platform. The impression of the model parameters on diverse flow fields is visualized through plotted graphs. Stability and convergence analysis is established for the authentication of the proposed model. Researchers are encouraged to conduct trials to authenticate the innovative consequences provided in this study, which could be obliging in the improved design of mechanical systems comprising the nanofluids that enables heat and mass transfer mechanism.