The purpose of this work is to analyze the convective horizontal flow Williamson-based magnetized hybrid nanofluid. Williamson fluid with heat transfer stimulated in a porous media over stretching surface. Two different type nanoparticles such as, molybdenum disulfide (MoS2) and copper (Cu) engine oil (Eo) as base are considered work. inspected based on Khanefer model. governing system transformed into nondimensionalized partial differential equations (PDE's) by utilizing nonsimilar transformation. analytically approximated using local nonsimilarity (LNS) perturbation approach which approximate nondimensional PDE's ordinary (ODEs). LNS ODEs simulated finite difference-based algorithm bvp4c. outcomes simulation for surface incorporating evolvement Nusselt number (Nu) distinct values prandtl compared previous published numerical results. appropriate range parameters evaluated detect variance physical quantities namely, velocity (f′(η)) fluid, temperature (θ′(η)) co-efficient skin friction (Cf). percentage difference between single nano-fluid nano-fluids made given tabular form. To best author knowledge, nonosimilar study hybrid-based nanofluid not yet investigated. This anticipated offer crucial information implementation innovative devices future serve an invaluable resource researchers looking at nanofluids under various assumptions.

Load

Load