Tiny particles thermal motile in magnetized chemically reacting upper-convective Maxwell stagnation point fluid with radiation

Abstract

The need to enhance industrial working fluid and material thermal strength for quality output of engineering and domestic devices, has increased diverse studies on non-Newtonian viscous fluid under different constraints. Various architectures and geometries have been considered for thermal propagation of fluid particles. As such, this study addresses thermal motility of tiny particles in magnetized chemically reacting upper-convective Maxwell stagnation point fluid with radiation owing to its usages. A partial-differential model is formulated under some certain assumptions and conditions, and with applicable similarity variables, a transformed invariant coupled ordinary-differential model is obtained. The solutions to the model are determined using Galerkin-weighted residual method. The computed outcomes are quantitatively tabulated and qualitatively demonstrated in graphs. The analysis revealed that the hydrodynamic bounding surface alongside with velocity profiles declines due to augmentation of the magnetic field and Deborah number terms.