Thermal Onsets of Viscous Dissipation for Radiative Mixed Convective Flow of Jeffery Nanofluid across a Wedge

The current analysis discusses Jeffery nanofluid's thermally radiative flow with convection over a stretching wedge. It takes into account the Brownian movement and thermophoresis of the Buongiorno nanofluid model. The guiding partial differential equations (PDEs) are modified by introducing the symmetry variables, leading to non-dimensional ordinary differential equations (ODEs). To solve the generated ODEs, the MATLAB function bvp4c is implemented. Examined are the impacts of different flow variables on the rate of transmission of heat transfer (HT), temperature, mass, velocity, and nanoparticle concentration (NC). It has been noted that the velocity and mass transfer were increased by the pressure gradient factor. Additionally, the thermal boundary layer (TBL) and nanoparticle concentration are reduced by the mixed convection (MC) factor. In order to validate the present research, the derived numerical results were compared to previous findings from the literature while taking into account the specific circumstances. It was found that there was good agreement in both sets of data.

Automated summary

The current study investigates the thermally radiative flow of Jeffrey nanofluid over a stretching wedge, considering the Brownian motion and thermophoresis effects. The governing partial differential equations are transformed into non-dimensional ordinary differential equations using symmetry variables. The MATLAB function bvp4c is utilized to solve the resulting ODEs. The impacts of different flow variables on heat transfer, temperature, mass, velocity, and nanoparticle concentration are examined.