Abstract
•Two-dimensional boundary layer flow of williamson hybrid nanofluid over a stretching sheet is studied.•The influence of different nanoparticles is explored while using single phase model.•The impact of shape factor and heat source is investigated.•A numerical procedure namely keller box method is used for the solution.•(SiO2−Cu/EO) hybrid nanofluid is better transfer source as compared to (Cu/EO) nanofluid.
Heat transfer is of vital importance because of its application in industries. A new nanofluid class called "hybrid nanofluid" is being used to boost ordinary fluids' heat transfer capabilities and has a higher heat exponent than nanofluids. The hybrid nanofluids (HNFs) are associated with two-element nanoparticles immersed in a base fluid. The steady hybrid nanofluid flowing and thermal transport characteristics passed overhead a slippery surface are investigated in this research. The impact of nanosolid particle shapes, Porosity material, heat source, viscous dissipative flow, and radiative flux are also involved in this examination. In a regime of partial-differential equations (PDEs), the predominant flow equations are formulated. Keller-box's computational technique is the utilized method to detect the self-similar solution for formulas transformed into ordinary-differential equations (ODEs) through appropriate transmutations. Williamson hybrid nanofluid has been considered for this work, which consists of double diverse kinds of nanoparticle, Copper (Cu) and Silicon dioxide (SiO2) in the rich viscous based fluid of kind EO (Engine Oil). The noteworthy result of this analysis is that the comparing thermal transmission level of such kind of fluid (SiO2Cu/EO) which has progressively more upsurges as compared to traditional nanofluids (Cu-EO). The lamina-shaped elements cause the utmost important thermal conductivity in the boundary- layer, whilst the lowermost thermal conductivity is detected in sphere shaped nanoparticles.