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Low-frequency resolvent analysis of the laminar oblique shock wave/boundary layer interaction

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posted on 2024-10-01, 09:46 authored by B Bugeat, J-Ch Robinet, J-C Chassaing, P Sagaut
Resolvent analysis is used to study the low-frequency behaviour of the laminar oblique shock wave/boundary layer interaction (SWBLI). It is shown that the computed optimal gain, which can be seen as a transfer function of the system, follows a first-order low-pass filter equation, recovering the results of Touber & Sandham (J. Fluid Mech., vol. 671, 2011, pp. 417–465). This behaviour is understood as proceeding from the excitation of a single stable, steady global mode whose damping rate sets the time scale of the filter. Different Mach and Reynolds numbers are studied, covering different recirculation lengths $L$ . This damping rate is found to scale as $1/L$ , leading to a constant Strouhal number $St_{L}$ as observed in the literature. It is associated with a breathing motion of the recirculation bubble. This analysis furthermore supports the idea that the low-frequency dynamics of the SWBLI is a forced dynamics, in which background perturbations continuously excite the flow. The investigation is then carried out for three-dimensional perturbations for which two regimes are identified. At low wavenumbers of the order of $L$ , a modal mechanism similar to that of two-dimensional perturbations is found and exhibits larger values of the optimal gain. At larger wavenumbers, of the order of the boundary layer thickness, the growth of streaks, which results from a non-modal mechanism, is detected. No interaction with the recirculation region is observed. Based on these results, the potential prevalence of three-dimensional effects in the low-frequency dynamics of the SWBLI is discussed.

History

Citation

B. Bugeat, J. C. Robinet, J. C. Chassaing, and P. Sagaut, “Low-frequency resolvent analysis of the laminar oblique shock wave/boundary layer interaction,” J. Fluid Mech. 942, A43 (2022).https://doi.org/10.1017/jfm.2022.390

Author affiliation

School of Engineering, University of Leicester

Version

  • VoR (Version of Record)

Published in

Journal of Fluid Mechanics

Volume

942

Publisher

Cambridge University Press (CUP)

issn

0022-1120

eissn

1469-7645

Acceptance date

2022-04-25

Copyright date

2022

Available date

2024-10-01

Language

en

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