Effects of Homogeneous-Heterogeneous Reactions in Flow of Electrical MHD Non-Newtonian Fluid with a Rotating Frame: An Analytical Approach

Abstract

This work provides an analytical method for the rotational flow of an electrical MHD Maxwell fluid that is limited by an elastic sheet that deforms linearly. Analysis of mass transfer is completed in the presence of HHR. The standard transformation is applied to translate the governing equations into similarity equations, which are then solved by the OHAM (optimal homotopy asymptotic technique). We have found that the OHAM technique works well, consistent, dependable, and efficient when it comes to solving highly nonlinear differential equations. For a certain range of Maxwell fluid parameters, concentration and velocity profiles are computed and explained. The rotation-strength parameter λ has a significant impact on the flow fields. The velocity curves are an oscillatory fading function of the dimensionless vertical distance for large values of λ. In the presence of an electric field, increasing the magnetic field first causes the velocity field to decrease, but eventually it starts to increase noticeably. As chemical reaction strengths increase, the concentration distribution at the sheet is observed to decrease. The current calculations are compared to those of previously published studies, and the results seem credible.