Free convective oscillatory flow due to inclined perpendicular shield subject to the thermos-diffusion and suction effects

An unsteady free convective flow of an electrically conducting viscous fluid due to accelerated inestimable inclined perpendicular shield has been presented in presence of heat and mass transfer phenomenon. The applications of thermos-diffusion and heat source are also incorporated. The chemical reaction consequences are considered in the concentration equation. The compelling meadow is considered to be homogeneous and practical perpendicular to the flow direction. Further, the oscillatory suction effects are also taken into observations for porous regime. The closed form expressions are resulted with implementation of perturbation approach. The non-dimensional expression for the proposed governing system is yield out with entertaining appropriate variables. The graphically influence of parameters is studied. Following to obtained observations, it is claimed that declining deviation in velocity is predicted with chemical reactive factor. Further, less thermal transport between container to fluid is noticed for radiative absorption parameter.

Automated summary

In this study, the unsteady free convective flow of an electrically conducting viscous fluid due to an accelerated inclined perpendicular shield was investigated in the presence of heat and mass transfer phenomenon. Thermos-diffusion and heat source applications were incorporated, and the effects of chemical reactions on the concentration equation were considered. The homogeneous and practical perpendicular meadow and the oscillatory suction effects in the porous regime were observed. Closed-form expressions were derived using a perturbation approach, and the non-dimensional expression for the governing system was obtained. The graphical influence of parameters was studied, revealing a predicted decline in velocity with the chemical reactive factor and a lower thermal transport between the container and fluid for the radiative absorption parameter.