MHD WILLIAMSON HYBRID NANOFLUID FLOW WITH CATTANEO-CHRISTOV FLUX MODEL

In this research, the numerical simulation of the Williamson hybrid nanofluid's MHD heat and mass transfer flow over a porous stretched sheet with Cattaneo-Christov heat and mass flux was found. The underlying physics of the situation are modelled by governing equations. After applying a suitable similarity transformation, these equations were converted into an ODE system and solved numerically using MATLAB and the BVP4C tool.The study's findings indicate that while raising the mass relaxation flux raises concentration distributions, increasing the heat relaxation flow raises temperature. To improve temperature and velocity distributions, an additional value of thermal radiation, heat generation, and Eckert number were observed. Due to the imposed electromagnetic force, a higher value of the magnetic field is observed. Also, the enhance in the thermal radiation parameter is observed to increase the velocity and temperature distributions. This research benefits from biomedical engineering, biological sciences, astrophysics, and geophysics.