Significance of thermal boundary layer analysis of MHD chemically radiative dissipative casson nanofluid flow over a stretching sheet with heat source

Abstract

A mathematical model that incorporates thermal emission, glutinous indulgence, heat source/sink, substance response, with suction was used to learn the MHD pour of Casson nanofluid in excess of a nonlinearly porous stretched page. There are a series of nonlinear ordinary differential equations that govern the biased differential equations through proper resemblance transformations, as well as then solved by the Homotopy Analysis Approach (HAM). Numerical data and plots are employed to examine the physical limitations on liquid speed, heat, and attentiveness. To examine the flow characteristics at the wall, the skin friction coefficients, local Nusselt digit, and Sherwood numbers are in addition evaluated. With much acclaim, a link between penetrable findings for specific cases is discovered.