Analysis of volume fraction of Casson Nanofluid flow over a flat moving plate with thermal radiation and nonuniform heat source/sink

Abstract

We provide numerary analysis of Casson nanofluids flowing through porous materials on stretched magnetic surfaces. The behavior of non-Newtonian liquids is described by the Casson liquid model. Similarity transformations are used to create nonlinear partial differential equations and are solved using numerical methods. Nusselt Number,Skin Friction Coefficient, Temperature, Velocity results are collected. Graphs are used to show the effects of physical factors on the flow and heat transfer properties of nanofluids. These include the Kasson parameter, the porosity parameter, the magnetic parameter, the radiation parameter, and the Prandtl number. Results show that the temperature profile increases while the velocity field decreases with increasing Casson nanofluidic parameters. A decrease in the thickness of the pulse boundary layer and an increase in the thickness of the thermal boundary layer can be seen with increasing magnetic parameters alone.