New insight into the spectra of turbulent boundary layers with pressure gradients

TL;DR

This paper analyzes turbulent boundary layers with pressure gradients using spectral analysis, revealing new scaling behaviors of different flow regions and scales at high Reynolds numbers.

Contribution

It introduces novel spectral scaling insights for turbulent boundary layers with pressure gradients, based on high-Reynolds-number data, highlighting differences from zero-pressure-gradient cases.

Findings

Small near-wall scales scale with viscous units.

Large scales near the wall scale with boundary-layer thickness.

Outer spectral peak location scales with displacement thickness.

Abstract

With the availability of new high-Reynolds-number ($Re$) databases of turbulent boundary layers (TBLs) it has been possible to identify in detail certain regions of the boundary layer with more complex behavior. In this study we consider a unique database at moderately-high $Re$, with a near-constant adverse pressure gradient (APG) (Pozuelo {\it et al.}, {\it J. Fluid Mech.}, {\bf 939}, A34, 2022), and perform spectral analysis of the Reynolds stresses, focusing on the streamwise component. We assess different regions of the APG TBL, comparing this case with the zero-pressure-gradient (ZPG) TBL, and identify the relevant scaling parameters as well as the contribution of the scales of different sizes. The small scales in the near-wall region up to the near-wall spectral peak have been found to scale using viscous units. In APG TBLs, the largest scales close to the wall have a better scaling with the boundary-layer thickness ($\delta_{99}$), and they are significantly affected by the APG. In the overlap and wake regions of the boundary layer, the small energetic scales exhibit a good scaling with the displacement thickness ($\delta^*$) while the larger scales and the outer spectral peak are better scaled with the boundary-layer thickness. Also note that the wall-normal location of the spectral outer peak scales with the displacement thickness rather than the boundary layer thickness. The various scalings exhibited by the spectra in APG TBLs are reported here for the first time, and shed light on the complex phenomena present in these flows of great scientific and technological importance.