Variable density and chemical reaction effects on heat and mass transfer of magnetic second-grade nanofluid flow under slip conditions
摘要
Slip flow, exponential thermal-density and second-grade nanofluid over horizontal stretching circular cylinder has many applications in heat exchangers, pipelines, rocket bodies, aircraft fuselages, submarine hulls, offshore structures, and flow bodies of industrial sectors. This research presents the thermal dependent density and chemical reaction effect on MHD second-grade nanofluid motion of heat and mass transmission over horizontal stretching circular cylinder with thermal-concentration slip. The importance of applied magnetic field is used for maximum increment of heat transport. The coupled partial differential equations of second-grade nanofluid are transformed into ordinary differential equations with help of well-defined similarity variable and stream functions. The average and central difference formula of finite-difference method with Newton–Raphson scheme are employed to find numerical outcomes of nonlinear ordinary differential equations through MATLAB software. Several physical parameters such as magnetic field (