Active and inactive components of the streamwise velocity in wall-bounded turbulence

Abstract

Townsend (1961) introduced the concept of active and inactive motions for wall-bounded turbulent flows, where the active motions are solely responsible for producing the Reynolds shear stress, the key momentum transport term in these flows. While the wall-normal component of velocity is associated exclusively with the active motions, the wall-parallel components of velocity are associated with both active and inactive motions. In this paper, we propose a method to segregate the active and inactive components of the 2-D energy spectrum of the streamwise velocity, thereby allowing us to test the self-similarity characteristics of the former which are central to theoretical models for wall-turbulence. The approach is based on analyzing datasets comprising two-point streamwise velocity signals coupled with a spectral linear stochastic estimation (SLSE) based procedure. The data considered span a friction Reynolds number range Reτ O(103) -- O(104). The procedure linearly decomposes the full 2-D spectrum () into two components, ia and a, comprising contributions predominantly from the inactive and active motions, respectively. This is confirmed by a exhibiting wall-scaling, for both streamwise and spanwise wavelengths, corresponding well with the Reynolds shear stress cospectra reported in the literature. Both a and ia are found to depict prominent self-similar characteristics in the inertially dominated region close to the wall, suggestive of contributions from Townsend's attached eddies. Inactive contributions from the attached eddies reveal pure k-1-scaling for the associated 1-D spectra (where k is the streamwise/spanwise wavenumber), lending empirical support to the attached eddy model of Perry & Chong (1982).