Radiation-Absorbing Chemically Reactive Nanofluid Flow with Heat Generation over a Porous Moving Vertical Plate under MHD and Buoyancy Effects

Abstract

Radiation-Absorbing chemically reactive nanofluid flow with heat generation over a porous
moving vertical plate under MHD and buoyancy effects is studied. In this study, a nanofluid (Cu − H2O)
and a pure fluid (water) are compared across a moving vertical plate with a porous surface surrounding it.
Aligned magnetic force (B0) effect is applied to the direction of the nanofluid flow. We assume that both
the temperature and the concentration remain constant while the plate moves with a constant velocity u0.
In order to resolve the governing equations, the Perturbation Technique is employed. This study uses graphs
and tables to examine and assess the impacts of several physical parameters, such as the radiation absorption
parameter and the heat generation/absorption parameter. Notably, the radiation absorption parameter raises
the temperatures, velocities, and shear stresses. Research and discussions have focused on shearing stress,
Nusselt number, and Sherwood number.