Radiative Darcy-Forchheimer hybrid nanofluid flow with thermal and bioconvection impacts over a stretching/shrinking sheet

The magnetohydrodynamics hybrid nanofluid (HNF) flow across a stretching & shrinking sheet is numerically studied. The HNF is synthesized by the scattering of SiO2 and MoS2 nanoparticles (NPs) in the ethylene glycol (EG). The impact of thermal radiation, surface permeability, heat absorption/generation, aligned magnetic field, and convective condition are also considered. The present research endeavors to discourse the research gap and offer remarkable perceptions of the above particular physical factors. The governing equations of HNF are renovated into the nonlinear dimensionless differential equations, which are numerically cracked through the well-known parametric continuation approach (PCA). The range of physical flow parameters on the flow rate, thermal field, and mass distributions have been considered according to the better convergence of the solution. From tabular and graphical results, it can be determined that the flow rate of HNF declines with the effect of the magnetic field and the rising number of SiO2 and MoS2 NPs in the EG. Furthermore, the outcome of bioconvective Schmidt number and Peclet number declines the density of microorganism distribution. The fluid velocity boosts with the effect of rotation parameter, while declines with consequences of the aligned magnetic field.