Effects of Second-Order Slip Flow and Variable Viscosity on Natural Convection Flow of (CNTs - Fe3O4)/Water Hybrid Nanofluids due to Stretching Surface

,is study deals with natural convection unsteady flow of CNTs - Fe3O4/water hybrid nanofluids due to stretching surface embedded in a porous medium. Both hybrid nanoparticles of SWCNTs - Fe3O4 and MWCNTs - Fe3O4 are used with water as base fluid. Effects of hybrid nanoparticles volume friction, second-order velocity slip condition, and temperature-dependent viscosity are investigated.,e governing problem of flow is solved numerically employing spectral quasilinearization method (SQLM) The results are presented and discussed via embedded parameters using graphs and tables.,e results disclose that the thermal conductivity of (CNTs - Fe3O4)/H2O hybrid nanofluids is higher than that of CNTs - H2O nanofluids with higher value of hybrid nanoparticle volume fraction. Also, the results show that momentum boundary layer reduces while the thermal boundary layer gros with higher values of temperature-dependent viscosity and second-order velocity slip parameters.,e skin friction coefficient improves, and the local heat transfer rate decreases with higher values of nanoparticle volume fraction, temperature-dependent viscosity, and second-order velocity slip parameters. Furthermore, more skin friction coefficients and lower local heat transfer rate are reported in the CNTs - Fe3O4/H2O hybrid nanofluid than in the CNTs - H2O nanofluid.,us, the obtained results are promising for the application of hybrid nanofluids in the nanotechnology and biomedicine sectors.

Automated summary

This study investigates the natural convection unsteady flow of CNTs - Fe3O4/water hybrid nanofluids due to stretching surface embedded in a porous medium. The effects of hybrid nanoparticles volume friction, second-order velocity slip condition, and temperature-dependent viscosity are analyzed. The results show that the thermal conductivity of (CNTs - Fe3O4)/H2O hybrid nanofluids is higher with higher value of hybrid nanoparticle volume fraction, and that higher temperature-dependent viscosity and second-order velocity slip parameters lead to reduced momentum boundary layer and increased thermal boundary layer.