Non-Newtonian Electrically Conducting Nano Fluid Heat and Mass Transfer Analysis Over a Vertical Cone with Convective Boundary Condition

Abstract

Electrically conducting, thermally radiative non-Newtonian Nano fluid heat and mass transfer features over a vertical permeable cone with chemical reaction and convective boundary condition is numerically scrutinized in this article. The system of transformed mathematical equations are numerically solved by utilizing the most efficient Finite element method. Brownian motion, Magnetic field, Lewis number, Biot number, Chemical reaction, Buoyancy ratio, Suction/Injection, Prandtl number, Thermal radiation parameters influence on Nanoparticle volume fraction, temperature and velocity scatterings is evaluated and the outcomes are plotted through graphs. Furthermore, the non-dimensional rates of concentration and heat transfer values are also premeditated. The temperature of the Nano fluid amplifies with rising values of Brownian motion parameter and this augmentation is more in non-Newtonian case than the Newtonian case. Addition of Convective boundary condition into the liquid flow intensifies the rates of heat transfer of non-Newtonian nanoliquid.