Binary Chemical Interaction and Nonlinearity Radiative Flux of Williamson Fluidic Flow Through Riga Plate

This Riga plate, which extends the configuration with permanent magnets and electrodes, may induce a wall-parallel Lorentz force over the magnetic field and exterior electrics, enabling efficient control of the fluid flow. In this paper, the focus is on considering the three-dimensional flow characteristics of Williamson fluid past the Riga plate in the absence of variable thermal properties. Many influential factors, such as convective boundary conditions of temperature, viscous dissipation, binary chemical reactions, and thermal radiation, are studied in their analysis. To address the study problem, dimensionless parameters are used to clarify the conductive partial differential equations. This dimensionless form was consequently determined mathematically by applying the shooting technique. The affected engineering parameters were interpreted graphically to appeal to physical interest. It was observed that the velocity distribution slows down into the viscosity parameter and stretching ratio constant. The enhanced temperature distribution was noticed in the increase in the thermal conductivity parameter. The rate of heat transport (130.56%) rises in the presence of Biot numbers. This causes significant increases in convective heat transport and heat energy.