Simulation of Hydromagnetic Williamson nanofluid flow with melting heat transfer and Activation Energy across a porous exponential stretching surface

Abstract

Abstract This discussion examines the combined effects of Brownian motion, radiation, Thermophorises, activation energy, suspended nanoparticles on hydromagnetic flow Williamson nanofluid produced by the melting process. In order to mathematically describe the system, a set of strongly non-linear coupled PDEs is used. A BVP4C MATLAB solver is used to resolve these equations. In addition, calculated findings are compared with previously published publications, and high levels of consistency are noted. The emerging Williamson MHD nanofluid sketches are graphically shown. Besides, tabular data on shear stress, heat transfer coefficient, and concentration is shown. Intriguingly, it can be shown that when the Williamson parameter increases, the momentum boundary layer corpulence decreases, while the thermal and solutal boundary layers corpulence increases. This research applies to chemical engineering coating materials such strong paints and aerosol manufacture.