Effects of thermophoresis and Brownian motion for thermal and chemically reacting Casson nanofluid flow over a linearly stretching sheet

The current research explores the problem of steady laminar flow nanofluid on a two dimensional boundary layer using heat transfer Cassona cross linearly stretching sheet. governing equations are partial differential which transformed into non-linear ordinary by some similarity transformation. converted form combined higher-order ODEswith set conditions solved means Runge-Kutta 4th-order approach along with shooting method. nanoparticle concentration profiles, velocity, and temperature examined taking account their influence Prandtl number, “Brownian motion parameter”, Lewis thermophoresis, Casson fluid parameter. It is reported that increase as Nt Nb increases causes thickening thermal layer. Also it observed that, there increment in profile for increasing values Brownian parameter energy distribution grows Thermophoresis comparison local Nusselt & Sherwood number has been tabulated respect to variation Motion Parameter All findings results graphically represented discussed.