Linear, nonlinear and transitional regimes of second mode instability

TL;DR

This paper investigates the linear and nonlinear evolution of second-mode instabilities in hypersonic boundary layers, revealing their role in transition to turbulence through detailed simulations and spectral analysis.

Contribution

It provides a comprehensive analysis of second-mode instability regimes, including nonlinear effects and transition mechanisms, using advanced DNS and spectral techniques.

Findings

Identification of a second growth region of the second-mode instability.

Nonlinear saturation leads to superharmonic generation and braided patterns.

Fundamental resonance dominates the transition process.

Abstract

The 2D second-mode is a potent instability in hypersonic boundary layers (HBLs). We study its linear and nonlinear evolution, followed by its role in transition and eventual breakdown of the HBL into a fully turbulent state. Linear stability theory (LST) is utilized to identify the second-mode wave through FS-synchronization, which is then recreated in linearly and nonlinearly forced 2D direct numerical simulations (DNSs). The nonlinear DNS shows saturation of the fundamental frequency, and the resulting superharmonics induce tightly braided ``rope-like'' patterns near the generalized inflection point (GIP). The instability exhibits a second region of growth constituted by the fundamental frequency, downstream of the primary envelope, which is absent in the linear scenario. Subsequent 3D DNS identifies this region to be crucial in amplifying oblique instabilities riding on the 2D second-mode ``rollers''. This results in lambda vortices below the GIP, which are detached from the ``rollers'' in the inner boundary layer. Streamwise vortex-stretching results in a localized peak in length-scales inside the HBL, eventually forming haripin vortices. Spectral analyses track the transformation of harmonic peaks into a turbulent spectrum, and appearance of oblique modes at the fundamental frequency, which suggests that fundamental resonance is the most dominant mechanism of transition. Bispectrum reveals coupled nonlinear interactions between the fundamental and its superharmonics leading to spectral broadening, and traces of subharmonic resonance as well.