Nanofluid flow past a nonlinearly stretched surface with shear flow and zero nanoparticle flux

Newtonian nanoliquid flow passing a nonlinearly stretched surface in attendance of shear flow under ‘blowing/suction’ has been measured. For passive control of the flow, zero flux of nanoparticles at the border has been considered. Two-phase liquid replica for nanoliquid is used. ‘Similarity transformations’ are used to alter main ‘partial differential equations’ into ‘ordinary differential equations’. With the help of 4th order Runge-Kutta method and ‘shooting technique’, solutions of the leading equations are obtained numerically. ‘Wall shear stress’ and ‘mass transfer’ coefficient rise but ‘heat transfer coefficient’ reduces for mounting strain rate ‘parameter’. ‘Temperature’ of the liquid diminishes but fluid's ‘velocity’ and concentration rise with growing ‘suction/injection parameter’. Temperature of the liquid goes up but fluid's ‘velocity’ reduces with the enhancement of ‘nonlinear stretching parameter’. According to the results presented here it is very clear that the relevant ‘parameters’ influence ‘flow, heat and mass’ transportation appreciably.