Numerical computations for thermally radiative viscoplastic magnetized nanomaterial capturing gyrotactic microorganisms, non-Darcian and transpiration aspects: A model for enhanced heat transference in modern industrial processes

Abstract

The fusion of electromagnetic (smart) functionalities with bioconvection phenomena is prevalent in contemporary engineering systems, spanning diverse applications like nano-sensors, surface finishing of components (coatings), fuel cells, robotics and biothermics. Taking cues from these advancements, we describe a computational simulation focusing on the steady bioconvective thermo-solutal flow of Casson (viscoplastic) nanofluid. The model investigates coating boundary layer transport along a vertical extending surface (substrate) to a non-Darcy porous matrix, incorporating elements such as thermal radiation and heat generation. The aim is to model the deposition process of novel bio-nano-smart coatings which offer advantages in thermal efficiency for emerging fuel systems. Additionally, heat generation, chemical reaction and suction/injection influences are considered. Some boundary solutal and convective thermal conditions are also included with Gyrotactic microorganisms. Using the Buongiorno nanoscale formulation, a redesigned Casson nanofluid model is built. With appropriate boundary circumstances, the basic conservation expressions for are derived using the boundary layer idea. With the help of proper