Effect of nonlinear thermal radiation on unsteady MHD flow of Maxwell nanoliquid over a porous vertical sheet with chemical reaction

The aim of the current article is to explore the impact of chemical reactions on magnetohydrodynamic mixed convective flow comprising Maxwell nanomaterial over a vertical porous surface with a convectively heated stretched surface. Heat transfers are also accounted for through thermal radiation. The modeled equations are formulated and transmuted into highly nonlinear partial differential equations into ordinary differential equations through suitable alteration, which is settled numerically through the Runge-Kutta method along with the shooting technique. The influences of various physical emerging parameters are plotted graphically for velocity, temperature, and concentration profiles. Friction factor, Nusselt number, and Sherwood number are plotted and discussed numerically. The outcome shows that the influences of fluid parameter epsilon lead to less viscosity and also a reduction in temperature as well as concentrations. The result revelas that enhancing Rd and E are esclated the temperature profile. Moreover, the skin friction C-f and Sherwood number Sh(x) are enhanced against various parameters. Finally, the work of previous literature is compared in limiting cases and achieved an excellent agreement.