Abstract
Within the context of a magnetic field and chemical reaction, this article investigates the impact of thermal radiation on the MHD Heat and Mass transfer of an oscillatory flow through a vertical plate that is embedded with porous material. Regular perturbation techniques are used to solve the nonlinear partial differential equations driving the heat and mass transfer processes. The momentum, energy, and concentration equations were derived from this linear transformation. The investigation and visual representation of the consequences of various pertinent flow-encased properties were undertaken. Researchers have found that increasing the thermal radiation parameters causes the fluid velocity to rise, but increasing the magnetic field parameter, Schmidt number, and Prandtl number causes the velocity profile to fall. Increasing the chemical reaction parameter also causes the concentration to climb. In addition, a thorough validation was carried out between the current work and the previous literature.
Published Version
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