Effects of Dufour and Heat Generation on MHD Casson Fluid Flows Past an Inclined Oscillating Plate with Chemical Reactions and Thermal Radiation in a Rotating Porous Medium

Effects of Dufour and Heat Generation on MHD Casson Fluid Flows Past an Inclined Oscillating Plate with Chemical Reactions and Thermal Radiation in a Rotating Porous Medium Chinnasamy Manigandan Sathiamoorthy Senthamilselvi Sundar Rajan Deepa Periyasamy Selvaraju

An analytical interpretation of unsteady-free convective hydromagnetic boundary layers is given in this work. It illustrates the impacts of Dufour radiation of heat, along with chemical reactions on a Casson fluid flowing by an inclined oscillating plate, a uniform magnetic field, and a rotating porous medium. The governing equations that had been solved by utilising the Laplace transform approach and the outcomes are shown. The numerical values of Casson fluid temperature, concentration, and velocity at the plate are visually represented for a range of relevant parameter values. The non-Newtonian fluid, which moves at a faster speed than the Newtonian fluid, has a Casson fluid parameter, which is examined and explained in this study. Moreover, the temperature trend increases with the Dufour number (Df), heat generation parameter (Q), and the reverse trend for thermal radiation parameter (R), Pradtl number (Pr), Schmidt number (Sc), as well as chemical reaction parameter (K). The concentration falls as the chemical reaction parameter (K) and Schmidt number (Sc) rise. We looked at the sped-up flow after the investigation to get measurable data, making sure to take into account things like Cason fluid parameter, Dofour number, and accumulation. Grashof values also findings speed decreases with increased radiation, chemical reaction, and Schmidth parameter levels. Our significant contribution to this research is an in-depth study of rotation with an inclined oscillating plate, which investigates the relationships between rotational forces, oscillation frequency, plate inclination, magnetic fields, and non-Newtonian features of Casson fluids. This work increases our understanding of how these parameters influence fluid behaviour, heat transfer, and mass transfer by offering a complete analytical framework that can be applied to a wide range of practical problems in fluids.In this research, my main contribution is rotation with an inclined oscillating plate.
11 20 2024 111 127 10.37934/arfmts.124.1.111127 https://semarakilmu.com.my/journals/index.php/fluid_mechanics_thermal_sciences/article/view/10688 https://semarakilmu.com.my/journals/index.php/fluid_mechanics_thermal_sciences/article/download/10688/7471 https://semarakilmu.com.my/journals/index.php/fluid_mechanics_thermal_sciences/article/download/10688/7471