Abstract
In this study, we investigated a non-Newtonian fluid stagnation point on a stretching surface with slip conditions using a phase flow model. Cu and Al2O3 nanoparticles were utilized, together with the base fluid H2O. The mathematical model has been built using flow assumptions and is theoretically acceptable. The momentum and energy equations are approximated using boundary layer approximations to create partial differential equations. The partial equations that are turned into ordinary differential equations are subjected to the appropriate similarity transformations. The bvp4c method is used to solve these equations numerically. Graphs and tables depict the effect of the physical parameters involved. Our findings are in good agreement with previous literature. Hybrid nanofluid achieves smaller values than nanofluid for the parameters F ''(0) and -theta'(0). Furthermore, for large values of the dimensionless parameter (N), F ''(0) and -theta'(0) grow, where as F'(xi) and (theta(xi)) increase for large values of phi(2). (C) 2021 Sharif University of Technology. All rights reserved.