Hall effects and viscous dissipation applications in peristaltic transport of Jeffrey nanofluid due to wave frame

The thermal aspect of nanofluid is significantly improved the heat and mass transportation phenomenon which complies importance in various engineering and industrial processes. The peristaltic transport of nanofluid is also important research area with applications of bioengineering and biotechnology. This research presents the thermal aspect of Jeffrey nanofluid in curved geometry channel with applications of Hall effects. The viscous dissipation and thermal radiation are also incorporated. The curvilinear coordinates are followed to model the problem. The long wavelength approximations are used for the formulation of problem. The numerical shooting procedure is implemented by using the MATHEMTICA software. The velocity magnitude declines in upper half and boundary layer phenomenon develops in lower half of the channel with enlarge variation of Hall parameter. A decreasing trend in temperature profile is observed with curvature parameter. For all types of waves, the magnetic parameter enhanced the heat transfer coefficient.

Automated summary

The thermal properties of nanofluid play a significant role in various engineering and industrial processes, especially in the field of bioengineering and biotechnology. This study investigates the peristaltic transport of nanofluid in a curved geometry channel with the application of Hall effects. The results show that the magnetic parameter enhances the heat transfer coefficient.