Non-invasive cell manipulation of entamoeba via magneto-plasmonic tetra-hybridized metamaterials: Entropy control strategies

Interactions between tetra-hybrid nanoparticles and non-Newtonian blood mediums lead to unique transport dynamics, influenced by magnetohydrodynamic forces and laser irradiation. Tetra-hybrid nanoparticles are an advanced class of nanomaterials that incorporate four distinct components gold (Au), silver (Ag), alumina (Al₂O₃), and titania (TiO₂). Each of these materials contributes unique properties, resulting in a multifunctional composite with enhanced optical, electrical, and thermal characteristics. Tapping into these synergistic nanoscale effects has the potential to inform various biomedical applications, including targeted drug delivery, hyperthermia cancer treatment, lab-on-a-chip devices, biosensing, and miniaturized diagnostics. Investigate streaming flow phenomena induced by interactions between tetra-hybrid nanocomposites and a non-Newtonian Jeffery fluid. Elucidate the complex transport dynamics altered by imposed magnetohydrodynamic forces and localized laser irradiation. Provide computational predictions regarding velocity, temperature, and particle concentration profiles. Capture intricate cellular trapping patterns arising from non-Newtonian rheology. Demonstrate the feasibility of precision fluid control through the use of biocompatible multimodal nano-assemblies. Capture multidimensional flow regimes under the influence of electromagnetic actuation and thermos-plasmonic effects. Resolve ordinary differential transport equations for momentum, energy, and mass species. Visualize two- and three-dimensional velocity streamlines, isotherms, and nanoparticle distribution contours. The graphical exploration of quantities relevant to engineering, such as heat transfer rate, mass transfer rate, skin friction coefficient, Nusselt number, Sherwood number, and optimization of entropy generation, is also depicted.