Hall current and thermal radiation effects of 3D rotating hybrid nanofluid reactive flow via stretched plate with internal heat absorption

Abstract

The present analysis deals with the impact of a magnetic field, joule heating, rotation parameter, and Hall current, as well as nonlinear thermal radiation, on a rotating hybrid Fe3O4/Al2O3 nanofluid over-stretched plate in the presence of a chemical reaction with thermophoresis and a Brownian motion parameter. The primary focus of this research is on the Brownian motion parameter. Similar transformations are used to translate the governing partial differential equations into a set of nonlinear ordinary differential equations. The shooting technique obtains numerical solutions for that system of equations. The impact of various entry parameters on transversal and longitudinal velocities, temperature, heat flow and surface shear stress are studied numerically and graphically. It was shown that there is a strong connection between the primary research when looking at particular situations that indicate how the current technique meets the convergence requirements. In addition, the physical relevance of the contributed parameters is shown via graphs and tables. The discovery demonstrates that an increase in the particle concentration of the hybrid nanofluid accelerates the flow of the fluid. In addition, factoring in dissipative heat makes it more likely that the fluid temperature will be increased to accommodate the participation of the particle concentration.