Abstract
The main purpose of the present research is to emphasize the importance of nanofluids that reacts chemically on a stretched sheet. The theoretical investigation of the nanofluid in three dimension flow along a stretched sheet is taken into consideration. As the stretched sheet is porous the velocity of the nanofluid slows down and simultaneously the temperature and concentration increases. When the rotation of the nanofluid is enhanced the velocity shows a reduction but the concentration and temperature rise. The chemical reaction of nanofluid is promoted by modified Arrhenius function. For energy of activation value increase, the concentration profile also increases. The impact of energy of activation under slip velocity is focused. The shooting Runge-Kutta techmique is utilized for solving numerically the resulting governing equations. Thermophoresis and Brownian motion of nanofluid is incorporated. Additionally, under convective surface condition the transference of heat and transference of mass is analyzed. When the porosity parameter is varied the velocity is inversely proportional, similar response is found in the concentration profile for activation energy. The graphical representation depicts the behaviour of several parameters towards temperature, velocity and profiles of concentration. Tables are utilized to examine the comparative analysis of Nusselt number, Skin friction coefficients and Sherwood number.