Numerical simulation of higher order chemical reactive flow of ternary hybrid nanofluid across an extending cylinder with heat generation and induction effects

Abstract

This study scrutinizes the influences of magnetic induction on the chemical reactive flow of trihybrid nanofluid with heat transfer in a boundary layer across an extended cylinder containing metallic nanoparticles. The trihybrid nanofluid is produced by dispersing silicon dioxide, cobalt ferrite nanoparticles in water and titanium dioxide, the base liquid. In energy conversion devices, thermal management systems, and chemical and petrochemical reactors where improved heat and mass transmission are essential, it is especially pertinent. Thermal conductivity is enhanced by the addition of ternary hybrid nanofluids, which makes the model applicable to cooling systems and nanocoating applications. The addition of chemical reactions, magnetic induction, and heat generation further increases its applicability to fields like nuclear engineering, biomedical devices, and smart manufacturing systems that need to precisely manage reactive transport phenomena. The basic fluid's thermos-physical properties are considerably improved by the addition of ternary hybrid nanoparticles. The bvp4c method is used to confirm the results' authenticity and accuracy. Figures and Tables are used to present and analyze the results. It has been noted that the liquid flow is decreased and magnetic induction profile is improved by the magnetic Prandtl number.