Stefan flow of MHD chemically reactive nanofluid past a plate with Navier slip and convective boundary condition

Abstract

This article plans to report the consequences of Navier slip and Stefan blowing on forced convection nanofluid flow past a plate in presence of a magnetic field with zero nanoparticle flux at the boundary which has not yet been addressed by any researcher and indicates the novelty of our work Nanofluid is considered to be chemically reactive and convective boundary condition has also been considered in this study. By the proper conversion by using similarity transformations, the leading PDEs (Partial Differential Equations) are shortened to ODEs (Ordinary Differential Equations) and those nonlinear equations are then numerically solved by shooting technique. Due to increase in magnetic parameter, fluid velocity and concentration augment (initially) but the temperature reduces. Compared to the result for in absence of magnetic field it is noted that, shear stress at the wall becomes almost double for half strength of the magnetic field. Moreover, in this case rate of heat transfer at the wall becomes almost double when the convective parameter becomes double. The concentration of nanoliquid declines by the rise in the speed of compound reaction. The outcome of this examination uncover a variety of inspiring distinctiveness which insist further study of the problem.