Spatial input-output analysis of large-scale structures in actuated turbulent boundary layers

TL;DR

This paper introduces a spatial input-output method to analyze how localized periodic actuation influences large-scale structures in turbulent boundary layers, matching experimental data and revealing flow dynamics.

Contribution

It develops a novel spatial input-output framework to study actuated turbulent boundary layers, linking theoretical analysis with experimental observations.

Findings

Large-scale structures match hot-wire measurements.

Shear stress distributions are consistent with canonical flows.

Quadrant analysis shows actuation frequency affects flow events.

Abstract

This paper develops a spatial input-output approach to investigate the dynamics of a turbulent boundary layer subject to a localized single frequency excitation. This method uses one-way spatial integration to reformulate the problem in terms of spatial evolution equations. The technique is used to examine the effect of localized periodic actuation at a given temporal frequency, based on an experimental set-up in which an active large-scale is introduced into the outer layer of a turbulent boundary layer. First, the large-scale structures associated with the phase-locked modal velocity field obtained from spatial input-output analysis are shown to closely match those computed based on hot-wire measurements. The approach is then used to further investigate the response of the boundary layer to the synthetically generated large-scale. A quadrant trajectory analysis indicates that the spatial input-output response produces shear stress distributions consistent with those in canonical wall-bounded turbulent flows in terms of both the order and types of events observed. The expected correspondence between the dominance of different quadrant behavior and actuation frequency is also observed. These results highlight the promise of a spatial input-output framework for analyzing the formation and streamwise evolution of structures in actuated wall-bounded turbulent flows.