Computational Analysis of Mixed Convection in a Blood-Based Hybrid Nanoliquid under Boussinesq Approximation in a Transient Regime

In recent times, nanoparticle-embedded flows are becoming household fluid in emerging medical interventions associated with thermal therapy. The place of thermal analysis is critical to underscore the potential of bio-nanofluidics and to perform a biothermal mechanical analysis of its performance during remediation strategies. This paper presents a thermal expedition of a hybrid nanofluid embedded in blood flow under a transient regime on the strength of a robust numerical scheme. The effect of heterogeneous–homogeneous chemical reaction on a magnetic field mediated hyperthermia over a porous substrate is mathematically expatiated in this report. Under Boussinesq approximation, the thermal model was formulated for the problem while homotopy analysis was employed to capture chemical dynamics and thermal transport in hybrid blood-based nanoliquid. Elaborate analysis of the prevailing physicochemical attributes of the flow under magnetic field imposition is sufficiently discussed within the framework of biological systems. These observations reported in this study could find application in the field of bio-nanotechnology in thermal-based therapy procedures in a realistic clinical scenario.