Wave interactions in a screeching jet

TL;DR

This paper investigates the complex interactions between shock waves, wave modes, and nonlinear effects in a screeching jet using advanced global and resolvent modeling techniques, revealing new insights into energy transfer mechanisms.

Contribution

It introduces a comprehensive modeling framework combining linear and nonlinear resolvent analysis to explain screech dynamics and energy redistribution in jets.

Findings

Identification of global eigenmodes linked to shock-cell interactions

Validation of a time-periodic screech mode matching experimental data

Demonstration of nonlinear self-interaction driving energy redistribution

Abstract

We use a series of global models to investigate the linear and nonlinear interactions between shock cells, Kelvin-Helmholtz waves, guided jet modes, and other fluctuations in a screeching jet. First, we identify a set of lightly damped global eigenmodes of the Navier-Stokes operator linearized about the mean flow and show that they result from interactions with different shock-cell wavenumbers. Second, we use resolvent analysis to study the linear input-output behavior of the jet and obtain a time-periodic representation of the screech mode, which compares favorably with experimental data. Third, we use harmonic resolvent analysis to study triadic interactions, including inter-frequency energy transfer, between the screech mode determined from resolvent analysis and other fluctuations in the jet. The components of the optimal harmonic resolvent mode at harmonics of the screech frequency match experimental observations that have not been previously predicted by global models. Fourth, we leverage a novel bilinear formulation of harmonic resolvent analysis to study the impact of the screech mode's nonlinear self-interaction on other fluctuations in the jet. We show that the forcing provided by this nonlinear self-interaction of the screech mode, along with its triadic interactions with other frequencies embedded within the harmonic resolvent operator, is sufficient to explain the redistribution of energy to other frequencies and the associated experimental observations. In aggregate, these findings underscore the critical role of triadic and nonlinear interactions in shaping screech dynamics and offer a promising workflow for studying similar interactions in other flows dominated by periodic motions.