Fluid sustainability by the effect of microrotational flow and chemical reactions in a vertical channel

The analysis of fluid sustainability and mass transfer features is an important research subject in mathematics, physics, and engineering science. Also, the traditional discipline of fluid dynamics gains a new dimension with the introduction of the idea of microrotational flow, which is the localized circulation of fluid around a rotating axis. The incorporation of this innovative approach with chemical interactions in a vertical channel offers significant potential for developing the study of fluid sustainability. This work investigates the dynamics of microrotational flow and chemical reactions using the numerical techniques. Thus, the present analysis examines the sustainability of fluid flow by combining microrotation and chemical reaction impacts. The proposed mechanism is mathematically expressed using the governing equations and the nonlinear coupled equations are solved analytically with suitable walls and conditions of the interface. The obtained solutions exhibit the nature of different parameters for the microrotational flow, velocity, and concentration fields. The findings are graphically shown and noted that the vortex viscosity parameter increases the microrotation flow speed and reduces the fluid velocity. Thermal Grashof number enhances the fluid flow. The presence of a chemical reaction parameter suppresses the fluid flow. Furthermore, the achieved solutions are in good agreement with the earlier literature.