Statistical computation for heat and mass transfers of water-based nanofluids containing Cu, Al 2 O 3 , and TiO 2 nanoparticles over a curved surface

Nanofluid is a specially crafted fluid comprising a pure fluid with dispersed nanometer-sized particles. Incorporation these nanoparticles into pure fluid results in a fluid with improved thermal properties in comparison of pure fluid. The enhanced properties of nanofluids make them highly sought after, in diverse applications, consisting of coolant of devices, heat exchangers, and thermal solar systems. In this study hybrid nanofluid consisting of copper, alumina and titanium nanoparticles on a curved sheet has investigated with impact of chemical reactivity, magnetic field and Joule heating. The leading equations have converted to normal equations by using appropriate set of variables and has then evaluated by homotopy analysis method. The outcomes are shown through Figures and Tables and are discussed physically. It has revealed in this study that Cu-nanofluid flow has augmented velocity, temperature, and volume fraction distributions than those of Al 2 O 3 -nanofluid and TiO 2 -nanofluid. Also, the Cu-nanofluid flow has higher heat and mass transfer rates than those of Al 2 O 3 -nanofluid and TiO 2 -nanofluid.