Flow of ferro-magnetic nanoparticles in a rotating system: a numerical investigation of particle shapes

A colloidal suspension of ferromagnetic particles, sized approximately 10 nm, in a carrier fluid (normally water) is termed as a ferrofluid. These fluids carry a wide range of practical applications in biomedical sciences, such as, magnetic separation of cells, magnetic drug targeting, and hyperthermia etc. Consequent to these applications, a keen attention, as they have got in recent times, is very understandable. With a similar inspiration, we present this work which investigates the flow of a Fe3O4-H2O magneto-nanofluid over a flat surface, in a rotating frame. A magnetic field, of strength Bo, has been imposed perpendicular to the surface. To see the effects of shape of ferromagnetic particles, a well-known Hamilton and Crosser's model has been used to formulate the governing equations. A numerical solution to the problem is obtained to simulate the flow behavior graphically. Variations in local Nusselt number and the coefficient of skin friction have also been captured. To validate the numerical scheme, a comparison with already existing result, simpler cases of the same problem, has also been made. A list of core findings is placed at the closure of this manuscript, in the conclusion section.