Computational analysis of thermal and mass transmit in a hydromagnetic hybrid nanofluid flow over a slippery curved surface

This study addresses a steady, incompressible and electrically conducting hybrid-nanofluid flow through a stretching curved surface. The consequences of velocity slip, convective heat and mass boundary conditions have been included in the study. We have opted for water as a base fluid and Molybdenum Disulphide for a nanofluid and Silver for a hybrid-nanofluid. In the cooling practice, the proficiency of a hybrid-nanofluid compared to a nanofluid is accomplished in detail. Through a similar transformation, we obtain non-linear ODEs from PDEs and solve subsequent equations numerically by employing the RK-4 shooting practice. An incitement of inspiring flow-factors on flow specific is accomplished precisely through figures and charts. The result shows that thermal plus concentration outlines have a linear relationship with thermal and concentration Biot numbers, and it discloses a reverse relationship with curvature factor. The outcomes certify that the highest rate of heat transport is enhanced by 85.27% and 99.62% for a hybrid-nanofluid and a nanofluid, respectively. No such research works were done before. Henceforth, consequences are unique and novel.