Three-Dimensional Radiative Bioconvective Flow of a Sisko Nanofluid with Motile Microorganisms

The progressive and enhanced thermal mechanisms of nanoparticles has motivated researchers to give attention this topic in recent years. synthesizing versatile applications such materials include cooling heating controlling processes, solar systems, energy production, nanoelectronics, hybrid-powered motors, cancer treatments, renewable systems. Moreover, the bioconvection nanofluids allows for some motivating era bioengineering biotechnology, as biofuels, biosensors, enzymes. With these interesting motivations applications, study elucidated upon three-dimensional flow a Sisko fluid (base fluid) presence nanofluid over stretched surface. additional features radiation were also incorporated modify analysis. rheological shear thinning thickening that are associated with comprehensively studied. problem was formulated using highly nonlinear coupled differential equations, which numerically simulated via shooting scheme. salient physical parameters graphically underlined view shear-thinning shear-thickening scenarios. results showed decrease velocity buoyancy ratio forces more conducive phenomenon. increase temperature profile due Biot number surface source parameter seemed be inflated scenario. A lower motile microorganism noted Lewis number.