Thermal insight to magnetized tri hybrid nanofluid (CuO-TiO2-SiO2)/blood with nonlinear radiated Effects: Applications to hyperthermia cancer treatment
Mohamed Arbi Khlifi, Faisal Mahroogi, Iskander Tlili
Abstract
: The tri hybrid nanofluids are modified class of nanomaterials with efficient heat transfer performances, conveying novel applications in advanced energy systems, heat exchangers and solar thermal collectors. Subject to biocompatible blood-based formulations, recently, the scientists have claimed the applications of such materials in the hyperthermia cancer treatments and targeted thermal therapies. Owing to such prestigious and motivated applications of tri hybrid nanofluids, the objective of current analysis is to presents biomedical applications of magnetized tri nanoparticles subject to human blood. Tri hybrid nanofluid thermal properties are endorsed by utilizing three different nanoparticles copper oxide (CuO), titanium oxide (TiO 2 ), and silicon oxide (SiO 2 ) with blood base material. The flow problem is incorporating the modified thermal theories. The rheological characteristics of human blood are justified by using the Casson fluid model. The thermal results are further supported with nonlinear radiated model and heat generation applications. More realistic convective thermal constraints for inspection of thermal simulations. After expressing the governing model in nonlinear differential equations, the numerical computations are performed via shooting scheme. The relative comparative thermal performances current model is examined for mono nanofluid , hybrid nanoparticles and tri-hybrid nanofluid . It has been predicted that enhancement in nanoparticles volume fraction increases the thermal phenomenon and heat transfer characteristics. In contrast, increment in Prandtl number and relaxation time parameter controls the heat transfer efficiency, indicating thermal resistance with tri hybrid nanofluid. Furthermore, thermal performance of tri nanofluid is more efficient as compared to mono and hybrid nanofluids. The simulated findings preserve significance in biomedical applications, especially in improving the drug delivery systems and enhancing thermal managements in hyperthermia treatments.