Symmetry-reduced low-dimensional representation of large-scale dynamics in the asymptotic suction boundary layer

TL;DR

This paper employs symmetry-reduced Dynamic Mode Decomposition to effectively identify low-dimensional, large-scale coherent structures in the asymptotic suction boundary layer, revealing potential self-sustained dynamics and interactions with near-wall structures.

Contribution

It introduces a symmetry-reduced DMD approach to analyze large-scale dynamics in the ASBL, overcoming challenges posed by continuous symmetries and capturing key flow features.

Findings

Large-scale dynamics are low-dimensional and potentially self-sustained.

Interactions with near-wall structures can be captured with few modes.

Symmetry reduction improves DMD performance in boundary layer analysis.

Abstract

An important feature of turbulent boundary layers are persistent large-scale coherent structures in the flow. Here, we use Dynamic Mode Decomposition (DMD), a data-driven technique designed to detect spatio-temporal coherence, to construct optimal low-dimensional representations of such large-scale dynamics in the asymptotic suction boundary layer (ASBL). In the ASBL, fluid is removed by suction through the bottom wall, resulting in a constant boundary layer thickness in streamwise direction. That is, the streamwise advection of coherent structures by the mean flow ceases to be of dynamical importance and can be interpreted as a continuous shift symmetry in streamwise direction. However, this results in technical difficulties, as DMD is known to perform poorly in presence of continuous symmetries. We address this issue using symmetry-reduced DMD (Marensi et al., J. Fluid Mech. 721, A10 (2023)), and find the large-scale dynamics of the ASBL to be low-dimensional indeed and potentially self-sustained, featuring ejection and sweeping events at large scale. Interactions with near-wall structures are captured when including only a few more modes.