An asymptotic theory of the roughness impact on inviscid Mack modes in supersonic/hypersonic boundary layers

In this paper, we develop a large-Reynolds-number asymptotic theory to describe the impact of a localised roughness element on oncoming inviscid first and second Mack modes in supersonic or hypersonic boundary layers. The height and width of the roughness are assumed to be of and , respectively, such that the induced mean-flow distortion is described by the triple-deck formalism, where is the Reynolds number based on the local boundary-layer displacement thickness . As the wavelength of the inviscid Mack mode is comparable with , its interaction with the roughness forms a multi-scale problem. The Mack mode in the bulk of the boundary layer is described by the inviscid Rayleigh equation, whose evolution near the roughness is formulated by use of the solvability condition. It is found that the dominant roughness effect is attributed to both the interaction of the oncoming perturbation with the mean-flow distortion in the main layer and the inhomogeneous forcing from the curved wall (Stokes layer). This theory enables us to probe the scattering process when the frequency approaches the synchronisation frequency, which is recognised as the critical site distinguishing the destabilising and stabilising roles of the roughness. An improved asymptotic theory is also developed, which increases the accuracy of the asymptotic prediction, especially at the intersection frequency of the first and second modes. We also carry out harmonic linearised Navier-Stokes calculations and direct numerical simulations to confirm the accuracy of the asymptotic predictions, and favourable agreements are obtained even when the roughness height is a quarter of the nominal boundary-layer thickness.

Automated summary

This paper develops a large-Reynolds-number asymptotic theory to describe the impact of a localized roughness element on inviscid first and second Mack modes in supersonic or hypersonic boundary layers. It is found that the roughness affects the oscillation frequency of the Mack modes, and identifies the critical frequency at which the roughness transitions from stabilizing to destabilizing effects. An improved asymptotic theory is also proposed to enhance the accuracy of predictions, confirmed through numerical simulations even with significant roughness height compared to the boundary layer thickness.