Inspection of hybrid nanoparticles flow across a nonlinear/linear stretching surface when heat sink/source and thermophoresis particle deposition impacts are significant

The aim of this paper is to highlight the impact of thermophoretic particle deposition (TPD) and heat source/sink on the steady two-dimensional laminar motion of Casson hybrid-type nanoliquid through a nonlinear stretched surface. Ordinary differential equations (ODEs) are created by taking a collection of partial differential equations (PDEs) and simplifying them using an appropriate similarity component. The reduced ODEs are then evaluated using the shooting method and Runge-Kutta-Fehlberg's fourth and fifth orders. Finally, tables and graphs are used to display the numerical data. It is seen that the fluid velocity step-downs when the porous parametric quantity and solid nanoparticle values increase. Heat distribution is enhanced with an enhancement in the heat source/sink constraint. Concentration goes down with an enhancement in thermophoretic constraint. The use of nanoparticles improves heat dispersion but reduces concentration in the linear case while increasing axial velocity in the nonlinear scenario.

Automated summary

This paper investigates the impact of thermophoretic particle deposition (TPD) and heat source/sink on the flow properties of Casson hybrid-type nanoliquid. Ordinary differential equations (ODEs) are used to simplify the partial differential equations (PDEs), and numerical methods are employed to solve the ODEs. The results reveal the significant influence of heat source/sink constraint on heat distribution, thermophoretic constraint on concentration, and the use of nanoparticles on heat dispersion and axial velocity.