Non-Newtonian Slippery Nanofluid Flow Due to a Stretching Sheet Through a Porous Medium with Heat Generation and Thermal Slip

Abstract The domains of engineering, electrical, and medicine all have a significant demand for nanofluids. Applications nanofluid flow include electronic device storage, industrial cooling heating frameworks, associated medicinal management information systems. Nanofluids are utilized generally as coolants in heat exchangers such thermostats, systems, radiators due to their enhanced thermal characteristics. This study aims explain the mixed convection phenomenon’s applications on impact Maxwell nanofluid. mass diffusivity is supposed be function concentration, whereas conductivity viscosity assumed functions temperature. It recommended consider additional effects slip, magnetic fields, generation phenomena. fluid motion was caused by vertically stretched sheet. dimensionless formulation suggested physical model shown suitable variables interacting. shooting approach used numerical simulations, it based lowering higher-order nonlinear differential equations first-order. slip velocity parameters direct local skin friction coefficient velocity, indicated research findings. Also, increase values parameter, porous parameter leads enhancement temperature distribution, while decline distribution can attributed same factors. A comparison also made with results described literature that currently available, superb agreement discovered.