Thermal Performance of Hybrid Nanoparticles on Radiative Flow with Slip Boundary Condition Under the Influence of Riga Plate

The rapid development of modern nanotechnology in industries and medical area have brought about the idea of mixing more than one nanoparticle in a base fluid which is called hybrid nanofluid. Hybrid nanofluid enhances the thermophysical properties of flow better compare to nanofluid. The main object of this study is to examine the thermal performance of hybrid nanoparticles on radiative flow with slip boundary condition under the influence of Riga Plate. This lead to a mathematical flow model in terms of highly non-linear partial differential equations (PDEs). The partial differential equations and their boundary conditions were reduced to ordinary differential equations (ODEs) using a suitable similarity variable. The resulting non-linear system of equations is then solved using Chebychev Collocation Method with the aid of Mathematica 11.0 software. It is found that the heat transfer rate of the hybrid nanofluid is higher as compared to the nanofluid. The imposed magnetic field of high strength is a better tool to control the motion of hybrid nanofluids inside the boundary layer. Thermal radiations and slip parameter are observed to be beneficial for thermal enhancement for both hybrid and nanofluids.