Significance of coupled effects of resistive heating and perpendicular magnetic field on heat transfer process of mixed convective flow of ternary nanofluid

The ternary nanofluids are significantly enhanced the thermal conductivity and heat transfer performance of conventional nanofluids. These fluids magnify the thermal properties like coolants in heat transport equipment such as electronic cooling, radiators and heat exchangers. In light of aforementioned importance, the aim of ongoing research is to investigate the thermal performance of water-based ternary nanoliquid which contains metallic and oxide nanoparticles (MoS2, SiO2, Au) through a cylinder subject to normal magnetic field, combined convection, resistive heating and internal heating species. By including these significant physical contribution; basic model transformed into final form and then investigated via RK-technique coupling with shooting scheme. The results for the heat transfer in ternary, hybrid and conventional nanoliquids are simulated under increasing parametric values. It is scrutinized that the amount of MoS2 nanoparticles from 0.1 to 0.6% and Ec (Eckert number) from 0.01 to 0.04 effectively enhanced the fluid of the functional fluids. In the presence of internal heating species, the rapid increase in the temperature in ternary nanoliquid is examined than that of hybrid and simple fluids. Further, the shear drag on the cylinder surface improved when the strength of mixed convection increased while these effects are better to control the temperature over the working domain.