Comparative analysis of nanofluid flows in the dilating squeezing porous channel with thermal jump and slip conditions

Abstract

This study investigates the behavior of the mono and hybrid nanofluid flows in an absorbent dilating/squeezing channel influenced by a magnetic field. The mono nanofluid is molded by inserting iron oxide (Fe3O4) nanoparticles into the blood (base fluid) and the targeted hybrid magnetic nanofluid is formed when the Cobalt iron oxide (CoFe2O4) nanoparticles are added into Fe3O4/blood nanofluid mixture. For a permeable channel, the slip boundary along with the thermal jump condition is imposed. The process for heat transfer is examined considering the Cattaneo-Christov heat flux. Throughout the analysis, platelet-shaped nanoparticles are used. The Tiwari and Das (single phase) nanoliquid flow model is adopted here. The ordinary differential equations (ODEs) are accomplished via similarity transformations and are numerically assessed using the bvp4c software. Moreover, the consequences of the resulting pertinent parameters on the streamlines, temperature, and velocity distributions are scrutinized using graphical representations. It is observed that the surface drag on the wall is weaker for the dilating/injection case as compared to the squeezing/suction scenario. Streamlines show how a suitable magnetic field may be used to regulate medicine distribution in the blood flow. An innovative mass-based model comprising mono and hybrid nanofluid flow models is discussed. A comparison of heat transfer between both is undertaken. The results indicate that increasing the magnetic parameter leads to an enhancement in heat transfer rate when the upper and lower walls are dilated with wall injection Conversely, if the upper and lower walls are squeezed with wall suction the heat transfer rate decreases. The novelty lies in the consideration of both types of models and making a comparison of these.