Chemical Reaction in Two-Phase Flow of Viscous-Casson Fluids in a Rotating Channel

Abstract

The goal of this thesis is to investigate the consequences of chemical reaction on two-phase flow of electrically conducting viscous-Casson (non-Newtonian) fluids in a rotating channel. In this analysis nth order chemical reaction is considered to see how this problem behave at different orders of chemical reactions. The general equations elaborating the present problem under implemented suppositions are transformed to ordinary differential equations. The numerical results for different emerging parameters are presented graphically. It is discovered from this investigation that fluid velocity decreases with changing values of angle of inclination and loading parameter, while increases with Hartmann number and Casson fluid parameter. It is also noticed that secondary velocity increases with Grashof number and rotating parameter. Magnetic induction decreases with Hartmann number and Casson fluid parameter. Furthermore, fluid temperature increases for large values of Prandtl and Eckert numbers. Increasing values of n and Schmidt number increases the mass transfer in the fluid.