Linear stability of nanofluid boundary-layer flow over a flat plate

TL;DR

This study examines the linear stability of nanofluid boundary-layer flow over a flat plate, revealing how nanoparticle density influences flow stability and identifying conditions for wave onset.

Contribution

It introduces a two-phase model incorporating Brownian motion and thermophoresis, analyzing their effects on flow stability and nanoparticle concentration layers.

Findings

Denser nanoparticles destabilize flow, lighter ones stabilize.

Brownian motion and thermophoresis effects are negligible.

Stability is affected by nanoparticle density and viscosity models.

Abstract

The linear stability of nanofluid boundary-layer flow over a flat plate is investigated using a two-phase model that incorporates Brownian motion and thermophoresis, building upon the earlier work of Buongiorno (2006). Solutions to the steady boundary-layer equations reveal a thin nanoparticle concentration layer near the plate surface, with a characteristic thickness of $O({\Rey}^{-1/2}{Sc}^{-1/3})$, for a Reynolds number $\Rey$ and Schmidt number $Sc$. When Brownian motion and thermophoresis are neglected, this nanoparticle concentration layer disappears, resulting in a uniform concentration across the boundary layer. Neutral stability curves and critical conditions for the onset of the Tollmien--Schlichting wave are computed for a range of nanoparticle materials and volume concentrations. Results indicate that while the effects of Brownian motion and thermophoresis are negligible, the impact of nanoparticle density is significant. Denser nanoparticles, such as silver (Ag) and copper (Cu), destabilise the Tollmien--Schlichting wave, whereas lighter nanoparticles, like aluminium (Al) and silicon (Si), establish a small stabilising effect. Additionally, stability characteristics are influenced by the viscosity model. Finally, a high-Reynolds number asymptotic analysis is undertaken for the lower branch of the neutral stability curve.