MHD Mixed Convection Hybrid Nanofluids Flow over a Permeable Moving Inclined Flat Plate in the Presence of Thermophoretic and Radiative Heat Flux Effects

Recent nanotech advancements have created a tremendous platform for the development of a superior ultrahigh performance coolant referred to as nanofluid for several industrial and engineering technologies. In this research, the impact of thermophoretic and viscous dissipation on the radiative mixed convective flow comprising hybrid nanofluid through an inclined permeable moving flat plate with a magnetic field is examined numerically. A model of non-linear differential equations is derived based on some realistic assumptions and tackled numerically using the bvp4c technique. The impact of the specific set of distinguished parameters on the velocity profiles, shear stress, temperature distribution profiles, heat transfer, concentration distribution profile, and mass transfer for the two dissimilar branch solutions are discussed in detail. In addition, it has been discovered that double solutions exist in the case of an opposing flow, while a single solution is observed in the case of an assisting flow. The temperature distribution profile escalates with the radiation parameter, while decelerating the velocity and concentration profiles.

Automated summary

Recent advancements in nanotech have paved the way for the development of a superior coolant called nanofluid, which has significant applications in various industries and engineering technologies. This research numerically examines the impact of thermophoretic and viscous dissipation on the mixed convective flow of hybrid nanofluid through an inclined permeable moving flat plate with a magnetic field. The study discusses the effects of different parameters on velocity profiles, shear stress, temperature distribution, heat transfer, concentration distribution, and mass transfer. It is found that opposing and assisting flows lead to different solutions, and the temperature distribution increases with the radiation parameter while decreasing the velocity and concentration profiles.