Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-14T11:13:43.116Z Has data issue: false hasContentIssue false

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

Published online by Cambridge University Press:  05 March 2021

Rahul Deshpande
Affiliation:
Department of Mechanical Engineering, University of Melbourne, Parkville, VIC3010, Australia
Jason P. Monty
Affiliation:
Department of Mechanical Engineering, University of Melbourne, Parkville, VIC3010, Australia
Ivan Marusic*
Affiliation:
Department of Mechanical Engineering, University of Melbourne, Parkville, VIC3010, Australia
*
Email address for correspondence: [email protected]

Abstract

Townsend (J. Fluid Mech., vol. 11, issue 1, 1961, pp. 97–120) 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 two-dimensional (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 analysing datasets comprising two-point streamwise velocity signals coupled with a spectral linear stochastic estimation based procedure. The data considered span a friction Reynolds number range $Re_{\tau }\sim {{O}}$($10^3$) – ${{O}}$($10^4$). The procedure linearly decomposes the full 2-D spectrum (${\varPhi }$) into two components, ${\varPhi }_{ia}$ and ${\varPhi }_{a}$, comprising contributions predominantly from the inactive and active motions, respectively. This is confirmed by ${\varPhi }_{a}$ exhibiting wall scaling, for both streamwise and spanwise wavelengths, corresponding well with the Reynolds shear stress cospectra reported in the literature. Both ${\varPhi }_{a}$ and ${\varPhi }_{ia}$ 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 one-dimensional spectra (where $k$ is the streamwise/spanwise wavenumber), lending empirical support to the attached eddy model of Perry & Chong (J. Fluid Mech., vol. 119, 1982, pp. 173–217).

Type
JFM Papers
Copyright
© The Author(s), 2021. Published by Cambridge University Press

1. Introduction and motivation

The attached eddy model (Perry & Chong Reference Perry and Chong1982; Marusic & Monty Reference Marusic and Monty2019), based on Townsend's attached eddy hypothesis (Townsend Reference Townsend1976), is a conceptual model through which the kinematics in a wall-bounded flow can be statistically represented by a hierarchy of geometrically self-similar attached eddies that are inertially dominated (inviscid), and randomly distributed in the flow field. Here, the term ‘attached’ refers to a flow structure whose geometric extent, i.e. the size of its velocity field, scales with its distance from the wall ($z$) and mean friction velocity ($U_{\tau }$). As per Townsend (Reference Townsend1976), the attached eddies have a population density inversely proportional to their height ($\mathcal {H}$), which varies in the range ${{O}}(z_{min})\lesssim \mathcal {H}$ $\lesssim$ ${{O}}(\delta )$, where $z_{min}$ corresponds to the start of the inertial region, while $\delta$ is the boundary layer thickness. At any $z$ $\gtrsim$ $z_{min}$, the cumulative contribution from the range of attached eddies results in the streamwise and spanwise turbulence intensities varying logarithmically as a function of $z$, while the wall-normal variance is a constant following

(1.1)\begin{equation} \left.\begin{aligned} {{\overline{u^2}}^+} & = {B_1} - {A_1} \ln\left(\frac{z}{\delta}\right), \\ {{\overline{v^2}}^+} & = {B_2} - {A_2} \ln\left(\frac{z}{\delta}\right), \\ {{\overline{w^2}}^+} & = {B_3},\quad \text{and}\quad {{\overline{uw}}^+} = {B_4}, \end{aligned}\right\} \end{equation}

where $A_1$, $A_2$, $B_1$, $B_2$, $B_3$ and $B_4$ are constants. Here, $u$, $v$ and $w$ are the velocity fluctuations along the streamwise ($x$), spanwise ($y$) and wall-normal ($z$) directions, respectively, while superscript ‘$+$’ denotes normalization by $U_{\tau }$ and kinematic viscosity ($\nu$). Recent literature (Jimenez & Hoyas Reference Jimenez and Hoyas2008; Baidya et al. Reference Baidya, Philip, Monty, Hutchins and Marusic2014; Lee & Moser Reference Lee and Moser2015; Orlandi, Bernardini & Pirozzoli Reference Orlandi, Bernardini and Pirozzoli2015) has reported substantial support for expressions corresponding to the lateral velocity statistics in (1.1), from experimental as well as simulation data, down to as low as $z^{+}$ $\sim$ 100. Support for a log law for ${\overline {u^2}}^{+}$ has been more convincing from high $Re_{\tau }$ experimental datasets (Hultmark et al. Reference Hultmark, Vallikivi, Bailey and Smits2012; Marusic et al. Reference Marusic, Monty, Hultmark and Smits2013) in comparison to low $Re_{\tau }$ simulations (Jimenez & Hoyas Reference Jimenez and Hoyas2008; Lee & Moser Reference Lee and Moser2015), likely owing to the lack of scale separation resulting in the self-similar contributions becoming obscured by the non-self-similar contributions at the same scale (Jimenez & Hoyas Reference Jimenez and Hoyas2008; Rosenberg et al. Reference Rosenberg, Hultmark, Vallikivi, Bailey and Smits2013; Baars & Marusic Reference Baars and Marusic2020b). Here, $Re_{\tau}$ = ${U_{\tau}}{\delta}/{\nu}$, where $\nu$ is the kinematic viscosity. Recently, Baars & Marusic (Reference Baars and Marusic2020b) were able to segregate these two contributions, consequently revealing the near-wall logarithmic growth (of ${\overline {u^2}}^{+}$) due to self-similar contributions down to $z^{+}$ $\sim$ 80, with a slope of 0.98 ($=A_{1}$; also known as the Townsend–Perry constant).

Given that the turbulence intensities in (1.1) equate to the integrated spectral energy in the respective velocity fluctuations (that is, $\overline {u^2}=\int _{0}^{\infty } {{\phi }_{uu}} {\,\textrm {d}{k_x}}$, where ${\phi }_{uu}$ is the one-dimensional (1-D) streamwise velocity spectrum and $k_{x}$ is the streamwise wavenumber), the contribution from the hierarchy of attached eddies also manifests itself in the energy spectra of the two wall-parallel velocity components; in the form of the so-called $k^{-1}_{x}$-scaling (Perry & Chong Reference Perry and Chong1982). This scaling has been predicted previously via dimensional analysis and other theoretical arguments (Perry & Abell Reference Perry and Abell1977; Perry, Henbest & Chong Reference Perry, Henbest and Chong1986; Nikora Reference Nikora1999; Katul, Porporato & Nikora Reference Katul, Porporato and Nikora2012), with Perry et al. (Reference Perry, Henbest and Chong1986) further arguing that the respective premultiplied spectra (${k^{+}_{x}}{{\phi }^{+}_{uu}}$, ${k^{+}_{x}}{{\phi }^{+}_{vv}}$) should plateau at a constant value equal to the rate of logarithmic decay ($A_{1}$ and $A_{2}$) for ${\overline {u^2}}^{+}$ and ${\overline {v^2}}^{+}$. These predictions, however, are rarely observed at finite $Re_{\tau }$, likely due to the flow containing a mixture of self-similar attached eddies and other non-self-similar flow structures. The difficulty in separating the two contributions may explain the lack of convincing empirical evidence of the $k^{-1}_{x}$-scaling for ${\phi }_{uu}$, and its association with $A_1$, in the literature (Nickels et al. Reference Nickels, Marusic, Hafez and Chong2005; Rosenberg et al. Reference Rosenberg, Hultmark, Vallikivi, Bailey and Smits2013; Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb).

Noting that experiments show that $\overline {u^2}^+$ and $\overline {v^2}^+$ varies with Reynolds number in the inertial region while $\overline {uw}^+$ does not (as per (1.1)), Townsend (Reference Townsend1961) commented that ‘it is difficult to reconcile these observations without supposing that the motion at any point consists of two components, an active component responsible for turbulent transfer and determined by the stress distribution and an inactive component which does not transfer momentum or interact with the universal component’. He further elaborated ‘that the inactive motion is a meandering or swirling motion made up from attached eddies of large size which contribute to the Reynolds stress much further from the wall than the point of observation’. This definition of active and inactive motions, however, seems to have been interpreted differently by some in the literature. Therefore, we attempt to clarify here our (and Townsend's) interpretation and emphasize its consistency with the attached eddy hypothesis (AEH).

1.1. Active and inactive motions

In the simplest attached eddy model, attached eddies are the only eddying motions present in the boundary layer, and they lead to ‘active’ and ‘inactive’ contributions. The key reason for this is the nature of the velocity signature from individual attached eddies in this inviscid model. The impermeability boundary condition at the wall enforces $w=0$ at the wall, but allows slip (and hence finite $u$ and $v$ at the wall). This is achieved by producing attached eddy velocity fields using a vortex structure with image vortex pairs in the plane of the wall. The result is a spatially localized $w$-velocity signature from the attached eddies – this is well illustrated in figure 1 of Perry et al. (Reference Perry, Henbest and Chong1986). Consequently, at any wall-normal location $z$ in the inertial region, active motions are solely due to the velocity fields of the attached eddies of height, $\mathcal {H}$ $\sim$ ${O}$($z$), and these contribute to $u(z)$, $v(z)$, $w(z)$ and hence ${\overline {uw}}$($z$). The inactive motions, however, are caused by the velocity fields from relatively large and taller attached eddies of height ${O}(z)\ll \mathcal {H}\lesssim {O}$($\delta$), and while these eddies contribute to $u(z)$ and $v(z)$, they make no significant contribution to $w(z)$. Hence, the inactive motions do not contribute to ${\overline {uw}}$($z$) (or $\overline {w^2}$($z$)). Therefore, while both active and inactive motions contribute to ${\overline {u^2(z)}}$ (and ${\overline {v^2(z)}})$, there are only active contributions to ${\overline {uw}}$($z$) (or $\overline {w^2}$($z$)). The consequence of this is that active motions are the component of attached eddy contributions that have pure wall scaling ($z$ and $U_\tau$). The remaining attached eddy contributions are the relatively large-scale inactive motions which, together with the inverse probability distribution of scales as per AEH, lead to the logarithmic decay of ${\overline {u^2}}^{+}$ and ${\overline {v^2}}^{+}$ (1.1) with $z$.

Figure 1. (a) Schematic of the experimental set-up in HRNBLWT showing relative positioning and movement of the four hot-wire probes ($HW_{1-4}$) for reconstructing the 2-D correlation corresponding to (i) $\varPhi$ and (ii) ${\varPhi }_{cross}$. Mean flow direction is along $x$. In the case of (ii), $HW_{3-4}$ are positioned at either $z_{r}\ll z_{o}$ or $z_{r} \gg z_{o}$, depending on the desired experiment (table 1). (b) Constant energy contours for ${\varPhi }$($z^{+}_{o} = z^{+}_{r}\approx 15) = 0.15$, computed from the present experimental and the converged DNS dataset of Sillero et al. (Reference Sillero, Jiménez and Moser2014), plotted as a function of viscous-scaled wavelengths. Estimates from the DNS are box filtered along $y$ to mimic the spatial resolution of the hot-wire sensors. Figure concept for (a) has been adopted from Deshpande et al. (Reference Deshpande, Chandran, Monty and Marusic2020a).

Given the above, the resulting attached eddy velocity fields can thus be decomposed following Panton (Reference Panton2007)

(1.2)\begin{equation} \left.\begin{aligned} u & = {u}_\textit{active} + {u}_\textit{inactive}, \\ v & = {v}_\textit{active}+ {v}_\textit{inactive}, \\ w & = {w}_\textit{active}, \end{aligned}\right\} \end{equation}

and as the active and inactive velocity fields are uncorrelated (Townsend Reference Townsend1961; Bradshaw Reference Bradshaw1967), the Reynolds stresses in (1.1) can also be decomposed as

(1.3)\begin{equation} \left.\begin{aligned} \overline{u^2} & = \overline{{u}^{2}}_\textit{active} + \overline{{u}^{2}}_\textit{inactive},\\ \overline{v^2} & = \overline{{v}^{2}}_\textit{active} + \overline{{v}^{2}}_\textit{inactive},\\ \overline{w^2} & = \overline{{w}^{2}}_\textit{active}, \\ \overline{uw} & = \overline{({u}_\textit{active})({w}_\textit{active})}. \end{aligned}\right\} \end{equation}

Here, the active and inactive motions can be deemed uncorrelated only if we ignore the nonlinear interactions across these motions, such as modulation, which have been shown to exist previously (Morrison Reference Morrison2007; Mathis, Hutchins & Marusic Reference Mathis, Hutchins and Marusic2009; Marusic, Mathis & Hutchins Reference Marusic, Mathis and Hutchins2010; Chernyshenko, Marusic & Mathis Reference Chernyshenko, Marusic and Mathis2012; Wu, Christensen & Pantano Reference Wu, Christensen and Pantano2019). However, such interactions will not contribute significantly to second-order velocity statistics (1.3), to which we restrict this paper. Modelling of skewness and higher-order statistics would, however, require modulation effects to be incorporated.

In real turbulent boundary layers, both self-similar and non-self-similar motions exist and contribute to the individual Reynolds stress components (Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb; Deshpande et al. Reference Deshpande, Chandran, Monty and Marusic2020a; Yoon et al. Reference Yoon, Hwang, Yang and Sung2020). Therefore, these additional non-self-similar contributions need to be recognized and appropriately accounted for while considering the decomposition in (1.3). They include the fine dissipative scales, as well as those corresponding to the inertial sub-range (Perry et al. Reference Perry, Henbest and Chong1986; Saddoughi & Veeravalli Reference Saddoughi and Veeravalli1994). These contributions, however, are small relative to those from the inertial motions (Perry et al. Reference Perry, Henbest and Chong1986), and may thus be deemed insignificant for a wall-bounded flow in the limit of $Re_{\tau }\rightarrow \infty$, which the inviscid AEH models. Other contributions include those from the very-large-scale motions or superstructures (SS), which are associated with tall and large $\delta$-scaled eddies spanning across the inertial region and contributing substantively to $\overline {u^2}$ and $\overline {v^2}$ (Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb; Deshpande et al. Reference Deshpande, Chandran, Monty and Marusic2020a; Yoon et al. Reference Yoon, Hwang, Yang and Sung2020). Evidence from the literature suggests that SS, however, do not contribute to $\overline {w^2}$, which is confirmed by the wall scaling exhibited by the 1-D $w$-spectra (Bradshaw Reference Bradshaw1967; Morrison, Subramanian & Bradshaw Reference Morrison, Subramanian and Bradshaw1992; Katul & Vidakovic Reference Katul and Vidakovic1996; Kunkel & Marusic Reference Kunkel and Marusic2006; Baidya et al. Reference Baidya, Philip, Hutchins, Monty and Marusic2017). Given the aforementioned characteristics, when considering these SS in the context of active and inactive contributions, the motions would also have an inactive signature in $\overline {u^2}$ and $\overline {v^2}$ in the inertial region. The total inactive contributions can thus be segregated as

(1.4)\begin{equation} \left.\begin{aligned} \overline{u^2}_\textit{inactive} & = \overline{{u}^{2}}_\textit{inactive, AE} + \overline{{u}^{2}}_\textit{inactive, SS},\quad \text{and}\\ \overline{v^2}_\textit{inactive} & = \overline{{v}^{2}}_\textit{inactive, AE} + \overline{{v}^{2}}_\textit{inactive, SS},\\ \end{aligned}\right\} \end{equation}

where $\overline {{u}^{2}}_\textit {inactive, SS}$ and $\overline {{u}^{2}}_\textit {inactive, AE}$ represent inactive contributions from the $\delta$-scaled SS and self-similar attached eddies, respectively. It is the presence of the former, which obscures the pure logarithmic decay of $\overline {{u}^{2}}_\textit {inactive}$ with $z$, as well as the true $k^{-1}_{x}$-scaling in the associated 1-D spectra (Jimenez & Hoyas Reference Jimenez and Hoyas2008; Rosenberg et al. Reference Rosenberg, Hultmark, Vallikivi, Bailey and Smits2013; Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb).

1.2. Present contributions

The present study first proposes a methodology to estimate $\overline {u^{2}}_\textit {active}$ and $\overline {u^{2}}_\textit {inactive}$ in the inertially dominated region of a canonical wall-bounded flow. Developing this capability of segregating the active from the inactive component, especially for $u$, is of use to the wall-turbulence modelling community, since it is $u_\textit {active}$ which contributes to the momentum transfer (1.3). The present methodology exploits the characteristic of the inactive motions (say at a given wall-normal distance $z_{o}$ in the inertial region) being chiefly created by large eddies relative to the active motions at $z_{o}$; these inactive motions are coherent across a significant wall-normal distance (Townsend Reference Townsend1976; Baars, Hutchins & Marusic Reference Baars, Hutchins and Marusic2017). For instance, Townsend (Reference Townsend1961, Reference Townsend1976) describes the inactive motions at $z_{o}$ as ‘swirling’ motions that influence the velocity field at all wall heights below $z_{o}$, including the wall shear stress, via low frequency variations (see also § 5.3 in Hwang Reference Hwang2015). Such motions have their spectral signatures reflected in the $u$-signals recorded at $z_{o}$ and below, down to the wall (say at a reference wall-normal location $z_{r}$). Recent work on the 1-D linear coherence spectrum by Baars et al. (Reference Baars, Hutchins and Marusic2017) and Deshpande, Monty & Marusic (Reference Deshpande, Monty and Marusic2019) has shown that a scale-by-scale cross-correlation of the synchronously acquired $u$-signals, at $z_{o}$ and $z_{r}$, isolates the energetic motions coherent across $z_{o}$ and $z_{r}$, which may be deemed as inactive for the case of $z_{r}\ll z_{o}$. Following (1.3), the isolated energy contribution from the inactive motions ($\overline {{u}^{2}}_\textit {inactive}$) can simply be subtracted from the total $u$-energy at $z_{o}$ ($\overline {u^2}$) to yield contributions predominated by the active motions at $z_{o}$. This makes the present approach different to previous analytical efforts, such as Panton (Reference Panton2007), wherein the active contributions were simply assumed to be proportional to the Reynolds shear stress to estimate the inactive contributions.

The methodology adopted here to segregate the active and inactive contributions, based on direct measurements, is also implemented later to separate the inactive motions into contributions from the self-similar attached eddies ($\overline {{u}^{2}}_\textit {inactive, AE}$) and from the $\delta$-scaled SS ($\overline {{u}^{2}}_\textit {inactive, SS}$). While contributions from the latter are known to be predominant across the inertial region, the self-similar attached eddy contributions to the inactive motions reduce significantly beyond the $\delta$-scaled upper bound of the logarithmic (log) region (Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb). By choosing the reference wall-normal location at this upper bound, say at a $z_{r}\gg z_{o}$, the scale-by-scale cross-correlation of the synchronously acquired $u$-signals at these $z_{o}$ and $z_{r}$ would isolate $\overline {{u}^{2}}_\textit {inactive, SS}$, which following (1.4) can be used to estimate $\overline {{u}^{2}}_\textit {inactive, AE}$.

To this end, two zero pressure gradient turbulent boundary layer (ZPG TBL) datasets, comprising multi-point $u$-fluctuations measured synchronously across a wide range of wall-normal (${{\rm \Delta} }z = |{z_{o}} - {z_{r}}|$) and spanwise (${{\rm \Delta} }y$) spacings, are considered. The datasets include measurements across the inertially dominated (log) region, and the TBLs span a decade of $Re_{\tau }$, permitting us to test for: (i) the universal wall scaling of the $u$-spectra associated with the active motions at $z_{o}$, and (ii) the $k^{-1}_{x}$-scaling of the $u$-spectra associated with the self-similar attached eddies inactive with respect to $z_{o}$. These data are first used to directly compute the two-dimensional (2-D) $u$-spectrum (Chandran et al. Reference Chandran, Baidya, Monty and Marusic2017; Chandran, Monty & Marusic Reference Chandran, Monty and Marusic2020), which gives a map of the energy contributions from eddies of various streamwise (${\lambda }_{x} = 2{{\rm \pi} }/{k_{x}}$) and spanwise (${\lambda }_{y} = 2{{\rm \pi} }/{k_{y}}$) wavelengths coherent across $z_{o}$ and $z_{r}$ (Deshpande et al. Reference Deshpande, Chandran, Monty and Marusic2020a). The two-point statistics are then used as an input to a spectral linear stochastic estimation (SLSE; Tinney et al. Reference Tinney, Coiffet, Delville, Hall, Jordan and Glauser2006; Baars, Hutchins & Marusic Reference Baars, Hutchins and Marusic2016) based procedure, which estimates the subset of the 2-D $u$-energy spectrum at $z_{o}$, associated with specific coherent motions coexisting at $z_{o}$.

2. ZPG TBL datasets

Two ZPG TBL datasets, consisting of synchronous multi-point $u$-velocity fluctuations, are considered for analysis in the present study. One is the $Re_{\tau }\approx 2000$ direct numerical simulation (DNS) dataset of Sillero, Jiménez & Moser (Reference Sillero, Jiménez and Moser2014), while the other is the $Re_{\tau }\approx 14\,000$ experimental dataset, a part of which has been reported previously in Deshpande et al. (Reference Deshpande, Chandran, Monty and Marusic2020a). A brief description of the two datasets is presented below.

2.1. Multi-point measurements at $Re_{\tau }\approx 14\,000$

The high $Re_{\tau }$ dataset was acquired in the large Melbourne wind tunnel (HRNBLWT) under nominal ZPG conditions and low free-stream turbulence levels (Marusic et al. Reference Marusic, Chauhan, Kulandaivelu and Hutchins2015) across its working section dimensions of ${\simeq }0.92\ \textrm {m}\times 1.89\ \textrm {m}\times 27\ \textrm {m}$. The very long length (27 m), and capability to generate free-stream speeds of up to 45 ms$^{-1}$, permit ZPG TBL measurements to the order of $Re_{\tau }\ ({=}\delta U_{\tau }/\nu )\approx 26\,000$ in this facility. In the present study, all measurements were conducted at a location approximately 20 m from the start of the working section, at a free-stream speed of $U_{\infty }\approx 20\ \text {ms}^{-1}$, resulting in a ZPG TBL at $Re_{\tau }\approx 14\,000$. The TBL thickness $\delta$ here is estimated via the modified Coles law of the wake fit (Jones, Marusic & Perry Reference Jones, Marusic and Perry2001) for both datasets. The multi-point measurements were made possible by a unique experimental set-up (Chandran et al. Reference Chandran, Baidya, Monty and Marusic2017) employing four hot-wire probes ($HW_{1-4}$), the arrangement of which is depicted in figure 1(a). Wollaston hot-wire probes of diameter, $d\approx 2.5\ \mathrm {\mu }$m and exposed sensor length, $l\approx 0.5$ mm were used for all the measurements, resulting in an acceptable length-to-diameter ratio of approximately 200 (Hutchins et al. Reference Hutchins, Nickels, Marusic and Chong2009) and a viscous-scaled sampling length, ${l^{+}}\ (={l}{U_{\tau }}/{\nu }) \approx 22$ for the given measurements. This hot-wire length is sufficiently small compared to the energetic spanwise wavelengths in the inertial region, which can be inferred from the spanwise spectra of the $u$-velocity component from any published DNS dataset (for instance, see figure 9 of Lee & Moser Reference Lee and Moser2015). The sensors were operated in a constant temperature mode using an in-house Melbourne University Constant Temperature Anemometer at an overheat ratio of 1.8 and at a viscous-scaled sampling rate, ${{\rm \Delta} }T^{+}\equiv {U^{2}_{\tau }}/{({\nu }{\,f_{s}})} \approx 0.5$, where $f_{s}$ refers to sampling frequency.

The experimental set-up, as depicted in figure 1, allows $HW_{1-2}$ to be traversed in the spanwise direction at a consistent wall-normal distance of $z_{o}$, while $HW_{3-4}$ remain stationary at a fixed spanwise and wall-normal ($z_{r}$) location throughout the measurement. To calibrate the probes, the same procedure as that employed by Chandran et al. (Reference Chandran, Baidya, Monty and Marusic2017) was implemented with $HW_{1}$, $HW_{2}$ and $HW_{4}$ simultaneously calibrated at a common wall-normal location by using the free-stream calibrated $HW_{3}$ as a reference. Simultaneously acquired $u$-signals from the four hot-wires are used to reconstruct the two-point correlation

(2.1)\begin{equation} {R_{{u_{o}}{u_{r}}}}({z_{o}},{z_{r}};{{\rm \Delta}}x,{{\rm \Delta}}y) = \overline{{{u}({z_{r}};x,y)}{{u}({z_{o}};x+{{\rm \Delta}}x,y+{{\rm \Delta}}y)}} \end{equation}

for the ${{\rm \Delta} }y$ range, $0 \le {{\rm \Delta} }y\le ({{\rm \Delta} }{y})_{max}$ and the total sampling duration ($T$) of the $u$-signals listed in table 1, with the overbar denoting ensemble time average. Taylor's frozen turbulence hypothesis, which considers all the coherent structures coexisting at $z_{o}$ to be convecting at the mean velocity at $z_{o}$ (i.e. $U_{c} = U(z_{o})$), is used to convert ${R_{{u_{o}}{u_{r}}}}$ from a function of time to that of ${{\rm \Delta} }{x}$, with $U_{c}$ denoting the convection velocity assumed at $z_{o}$. Following this, the 2-D Fourier transform of ${R_{{u_{o}}{u_{r}}}}$ is computed to obtain the 2-D spectrum as

(2.2)\begin{align} {{\phi}_{{u_{o}}{u_{r}}}}({z_{o}},{z_{r}};{k_{x}},{k_{y}}) &= \int \int_{-{\infty}}^{\infty} {R_{{u_{o}}{u_{r}}}}({z_{o}},{z_{r}};{{\rm \Delta}}x,{{\rm \Delta}}y) \nonumber\\ &\quad \times {\exp({-{j2{\rm \pi}({k_{x}}{{\rm \Delta}}x + {k_{y}}{{\rm \Delta}}y)}})}\,\textrm{d}({{\rm \Delta}}x)\,\textrm{d}({{\rm \Delta}}y), \end{align}

with $j$ a unit imaginary number.

Table 1. A summary of the ZPG TBL datasets comprising synchronized multi-point $u$-signals at $z^{+}_{r}$ and $z^{+}_{o}$ used to compute two types of 2-D $u$-spectra, ${\varPhi }$ and ${\varPhi }_{cross}$. The terminology has been described in § 2.1 and figure 1. Underlined values represent the approximate upper bound of the log region (0.15${Re_{\tau }}$; Marusic et al. Reference Marusic, Monty, Hultmark and Smits2013), while the values in bold represent the near-wall reference location. Superscript ‘$+$’ denotes normalization in viscous units.

For this study, we are only concerned with two types of 2-D spectra, ${\varPhi }$ and ${\varPhi }_{cross}$ which are defined as

(2.3)\begin{equation} \left.\begin{aligned} {\varPhi}(z^{+}_{o};{{\lambda}_{x}},{{\lambda}_{y}}) & = |{k^{+}_{x}}{k^{+}_{y}}{{\phi}^{+}_{{u_{o}} {u_{o}}}}({z^{+}_{o}};{{\lambda}_{x}},{{\lambda}_{y}})| \quad \text{and}\\ {{\varPhi}_{cross}}(z^{+}_{o},z^{+}_{r};{{\lambda}_{x}},{{\lambda}_{y}}) & = |{k^{+}_{x}}{k^{+}_{y}}{{\phi}^{+}_{{u_{o}}{u_{r}}}}({z^{+}_{o}},{z^{+}_{r}}; {{\lambda}_{x}},{{\lambda}_{y}})|, \end{aligned}\right\} \end{equation}

with the ${R_{{u_{o}}{u_{r}}}}$ corresponding to the former and latter, reconstructed via hot-wire arrangements depicted in figure 1(a,i) and 1(a,ii), respectively. Here, $z^{+}_{o} = {{z_{o}}{U_{\tau }}}/{\nu }$ and $k^{+}_{x} = {{k_{x}}{\nu }}/{U_{\tau }}$ (with similar definitions for other associated terms), where the superscript ‘$+$’ indicates normalization in viscous units. Table 1 details the exact wall-normal locations for which ${\varPhi }$ and ${\varPhi }_{cross}$ are computed, with ($||$) referring to the modulus operation. The present analysis is focused in the inertially dominated region, considered nominally to exist beyond $z^{+}_{o}\gtrsim 100$ (Nickels et al. Reference Nickels, Marusic, Hafez and Chong2005; Lee & Moser Reference Lee and Moser2015; Chandran et al. Reference Chandran, Baidya, Monty and Marusic2017; Baars & Marusic Reference Baars and Marusic2020a), based on the empirical evidence discussed in § 1. While ${\varPhi }$ represents contributions from all coexisting motions at $z_{o}$, ${\varPhi }_{cross}$ consists of contributions from only those motions that are coherent across $z_{o}$ and $z_{r}$ (Deshpande et al. Reference Deshpande, Chandran, Monty and Marusic2020a). Both these spectra are used as an input to the SLSE methodology (§ 3) to estimate subsets of ${\varPhi }$($z_{o}$) representing contributions from a specific family of coherent motions coexisting at $z_{o}$. Also, ${\varPhi }_{cross}$ has been estimated for two different reference wall-normal positions ($z_{r}$; table 1), each targeted at isolating specific contributions. The measurements to obtain ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 0.15Re_{\tau }$), however, were conducted following the same methodology as that adopted for ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 15$), which has been reported previously in Deshpande et al. (Reference Deshpande, Chandran, Monty and Marusic2020a) and may be consulted for further details.

The present study also reports the first measurements of ${\varPhi }$ in the near-wall region ($z^{+}_{o}=z^{+}_{r}\approx 15$), which is required as per the SLSE methodology (§ 3) being adopted in the present study. Figure 1(b) compares the constant energy contour for this experimentally estimated ${\varPhi }$ against the same computed from the converged 2-D $u$-correlations available from the DNS dataset of Sillero et al. (Reference Sillero, Jiménez and Moser2014). While a reasonable overlap of contours is observed in the small-scale range (figure 1b), when plotted as a function of viscous-scaled wavelengths, a prominent ‘footprint’ can be noted appearing for the large scales with increase in $Re_{\tau }$. This is representative of the increasing influence of the large scales in the near-wall region with increase in $Re_{\tau }$, as discussed by Hutchins & Marusic (Reference Hutchins and Marusic2007) and Hutchins et al. (Reference Hutchins, Nickels, Marusic and Chong2009). Here, the spectra from the DNS are box filtered for better one-to-one comparison with the experimental spectrum, wherein the energy in the small scales is underestimated due to the spatial resolution of the hot-wire sensor (Hutchins et al. Reference Hutchins, Nickels, Marusic and Chong2009). The box filtering is carried out along the $y$-direction, by following the same methodology as outlined in Chin et al. (Reference Chin, Hutchins, Ooi and Marusic2009), taking into consideration the viscous-scaled hot-wire sensor length corresponding to the measurements ($l^{+}\approx 22$). Another thing to note here is that the contour corresponding to the experimental spectrum deviates significantly from the low $Re_{\tau }$ DNS estimates at large wavelengths. This is possibly due to the failure of Taylor's hypothesis for these large scales in the near-wall region (del Álamo & Jiménez Reference del Álamo and Jiménez2009; Monty & Chong Reference Monty and Chong2009). This inconsistency, however, does not affect any of the forthcoming analysis since all the calculations (§ 3) for the experimental dataset are carried out in the frequency domain before converting to ${\lambda }_{x}$ via Taylor's hypothesis.

2.2. DNS dataset

A low $Re_{\tau }$ dataset from the ZPG TBL DNS of Sillero et al. (Reference Sillero, Jiménez and Moser2014) is also considered in the present study. Thirteen raw DNS volumes, each of which is a subset of their full computational domain between $x\approx 28.4\delta$ and $x\approx 40.3\delta$, are selected to ensure a limited $Re_{\tau }$ increase along $x$. Streamwise velocities $u$($z^{+}_{o}$;$x$,$y$) extracted from these fields are used to compute ${\varPhi }$($z^{+}_{o}$) and ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 15$) following (2.1)–(2.3), at $z^{+}_{o}$ and $z^{+}_{r}$ consistent with the experimental dataset (table 1). A similar analysis is also conducted using the instantaneous wall-normal velocity fluctuations, $w$($z^{+}_{o}$;$x$,$y$) extracted from this dataset. It is used to establish the efficacy of the SLSE-based methodology being implemented here to segregate active and inactive contributions, the results from which are discussed in appendix A.

3. Energy decomposition into active and inactive contributions

As discussed in § 1, the inactive motions at $z_{o}$ are predominantly large motions (with respect to $z_{o}$) that are coherent across a significant wall-normal distance. This forms the basis for decomposing ${\varPhi }$($z_{o}$). Classically, the size and scaling of the coherent structures have been interpreted via two-point cross-correlations (Ganapathisubramani et al. Reference Ganapathisubramani, Hutchins, Hambleton, Longmire and Marusic2005; Hutchins & Marusic Reference Hutchins and Marusic2007). Correlations represent contributions from a wide range of scales which, during the ensemble averaging procedure, do not distinguish the individual contributions from the small and large motions (Baars et al. Reference Baars, Hutchins and Marusic2017; Deshpande et al. Reference Deshpande, Monty and Marusic2019). Therefore, the present investigation has been conducted entirely in the spectral domain. Previous studies (Balakumar & Adrian Reference Balakumar and Adrian2007) employing the spectral approach have utilized a sharp streamwise spectral cutoff to segregate the large motions from the rest of the turbulence, which inherently comes with a drawback that the estimates are cutoff dependent.

Here, the intention is to perform an unconditional linear decomposition of ${\varPhi }$($z_{o}$) into its inactive and residual component (figure 2) by utilizing the scale-by-scale coupling between $u$-signals simultaneously measured at two wall-normal locations, $z^{+}_{o}$ (in the inertially dominated region) and ${z^{+}_{r}} \approx 15$, ensuring $z^{+}_{r}\ll z^{+}_{o}$. A linear decomposition was deemed sufficient for this purpose given the fact that the coupling has been computed between velocity signals at both ends (Guezennec Reference Guezennec1989; Baars et al. Reference Baars, Hutchins and Marusic2016), and that the present interests are limited to the second-order velocity statistics (§ 1). ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 15$), which is considered here at various $z^{+}_{o}$ for both the experimental and DNS datasets, represents this scale-by-scale coupling. On comparing ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 15$) and ${\varPhi }$($z^{+}_{o}$) contours from the two datasets at various $z^{+}_{o}$ in figure 2(a,c), the former is representative of energetic large scales that can be associated with the motions inactive at $z^{+}_{o}$. It is evident that ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 15$) also inherently comprises energy contributions from the $\delta$-scaled SS (${\lambda }_{x}\gtrsim 6\delta$), which are known to extend from the wall and span across the inertial region (Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb; Deshpande et al. Reference Deshpande, Chandran, Monty and Marusic2020a; Yoon et al. Reference Yoon, Hwang, Yang and Sung2020). We use ${\varPhi }_{cross}$ in conjunction with the SLSE (Tinney et al. Reference Tinney, Coiffet, Delville, Hall, Jordan and Glauser2006; Baars et al. Reference Baars, Hutchins and Marusic2016) to obtain a linear stochastic estimate of the spectrum (${\varPhi }_{ia}$) associated with the inactive motions at $z_{o}$ following

(3.1)\begin{equation} {{{\varPhi}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})} = {\frac{{\left[{{\varPhi}_{cross}}({z^{+}_{o}}, {z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}}) \right]}^{2} }{ {{\varPhi}}({z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}})}}. \end{equation}

Interested readers may refer to appendix A to see the step-by-step procedure to arrive at the expression in (3.1). The mathematical operation in the above equation suggests ${{\varPhi }_{ia}}$($z^{+}_{o}$) to be essentially a normalized version of ${{\varPhi }_{cross}}$(${z^{+}_{o}},{z^{+}_{r}}\approx 15$), with the scale-by-scale normalization done by ${{\varPhi }}$(${z^{+}_{r}}\approx 15$), the contours for which are also plotted in figure 2(a,c). It should be noted here that the calculations in (3.1) are carried out in the frequency domain for the experimental dataset, with the conversion to ${\lambda }_{x}$ by invoking Taylor's hypothesis, using $U_{c}=U$($z_{o}$) (Baars et al. Reference Baars, Hutchins and Marusic2016, Reference Baars, Hutchins and Marusic2017). Following the linear superposition assumption in (1.3), ${\varPhi }_{ia}$ can be simply subtracted from ${\varPhi }$ to leave a residual

(3.2)\begin{equation} {{{\varPhi}_{a}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})} = {{\varPhi}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})} - {{{\varPhi}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})}, \end{equation}

with ${\varPhi }$, ${\varPhi }_{ia}$ and ${\varPhi }_{a}$ representative of $\overline {u^2}^{+}$, $\overline {u^{2}}^{+}_\textit {inactive}$ and $\overline {u^{2}}^{+}_\textit {active}$, respectively. If the flow consisted of only active and inactive inertial motions, ${\varPhi }_{a}$ and ${\varPhi }_{ia}$ would be the active and inactive components, respectively. However, we refer to ${\varPhi }_{a}$ as the residual spectrum, given that it also comprises small contributions from the fine dissipative scales as well as those corresponding to the inertial sub-range (§ 1). We limit their influence in the present analysis by focusing our investigation on the high energy contours of ${\varPhi }_{a}$, which are associated predominantly with the inertial active motions.

Figure 2. (a,c) Constant energy contours for ${\varPhi }$($z^{+}_{o}$), ${\varPhi }_{cross}$($z^{+}_{o}$, $z^{+}_{r}\approx 15$) and ${\varPhi }$($z^{+}_{r}\approx 15$) at an energy level of 0.15 plotted for (a) $z^{+}_{o}\approx 100$ and (c) $z^{+}_{o}\approx 0.15Re_{\tau }$. (b,d) Constant energy contours for ${\varPhi }_{ia}$($z^{+}_{o}$) and ${\varPhi }_{a}$($z^{+}_{o}$), computed via (3.1) and (3.2), plotted at the same energy level and $z^{+}_{o}$ as in (a,c), respectively. In (ad), contours on the left side correspond to those computed from the DNS data while those on the right are from the experimental data. Dashed green lines represent the linear relationship, ${\lambda }_{y}\sim {\lambda }_{x}$.

Figure 2(b,d) shows the constant energy contours for the two components ${\varPhi }_{ia}$($z^{+}_{o}$) and ${\varPhi }_{a}$($z^{+}_{o}$), computed via (3.1) and (3.2), using the corresponding inputs plotted in figure 2(a,c), respectively. While ${\varPhi }_{ia}$ takes up the large-scale portion of ${\varPhi }$, ${\varPhi }_{a}$ is restricted to the small-scale end of the spectrum. This is in spite of the fact that ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r} \approx 15$) also comprises contributions from relatively small scales at $z^{+}_{o}\approx 100$ (figure 2a) and can be explained by the linear transfer kernel (A 4) and (A 5), which has been computed at various $z^{+}_{o}$ for the DNS dataset and shown in figure 8(a) in appendix A. Interestingly, at $z^{+}_{o}\approx 100$ (figure 2b), both ${\varPhi }_{a}$($z^{+}_{o}$) and ${\varPhi }_{ia}$($z^{+}_{o}$) can be seen to follow the ${\lambda }_{y}$ $\sim$ ${\lambda }_{x}$ relationship representative of geometric self-similarity, which is otherwise obscured for ${\varPhi }$ in the intermediate- and large-scale range (Chandran et al. Reference Chandran, Baidya, Monty and Marusic2017, Reference Chandran, Monty and Marusic2020; Deshpande et al. Reference Deshpande, Chandran, Monty and Marusic2020a). The self-similar characteristic of ${\varPhi }_{ia}$ and ${\varPhi }_{a}$ is consistent with the hypothesis of Townsend (Reference Townsend1961, Reference Townsend1976), who originally described both the active and inactive motions to be associated purely with the attached eddy contributions, but conforming to a different range of scales: the active motions at $z^{+}_{o}$ conform to the attached eddies with height, $\mathcal {H}\sim {{O}}(z_{o})$, while the inactive motions conform to relatively large eddies with ${{O}}(z_{o})\ll \mathcal {H}\lesssim {{O}}(\delta )$ (see § 1). Consequently, the contribution from the attached eddies to ${\varPhi }_{ia}$ reduces with increase in $z^{+}_{o}$, with energy contours at $z^{+}_{o}\approx 0.15Re_{\tau }$ (figure 2d) corresponding predominantly to the tall $\delta$-scaled SS coexisting across the inertial region. This likely explains why ${\varPhi }_{ia}$ contours do not align along ${\lambda }_{y}$ $\sim$ ${\lambda }_{x}$ at $z^{+}_{o}$ farthest from the wall. It also forms the basis for choosing $z^{+}_{r}\approx 0.15Re_{\tau }$ as a reference wall height while implementing the SLSE methodology to isolate the superstructure contributions, which will be discussed later in § 5.1. Parameter ${\varPhi }_{a}$, on the other hand, comprises a significant range of scales irrespective of the change in $z^{+}_{o}$, with the contours simply shifting to relatively larger scales, which is suggestive of its distance-from-the-wall ($z_{o}$) scaling. Having defined the procedure to obtain ${\varPhi }_{a}$ and ${\varPhi }_{ia}$, next we test for $z_{o}$- and $\delta$-scaling to verify the extent to which the respective spectra can be associated with the active and inactive motions.

4. Active component of the streamwise velocity spectrum

Figure 3(a,b) shows the constant energy contours of ${\varPhi }_{a}$ (${=}0.15$), computed from both DNS and experimental datasets, plotted as a function of wavelengths scaled with $z_{o}$ and ${\delta }$, respectively. The contours are plotted for ${\varPhi }_{a}$ across $100 \lesssim z^{+}_{o}\lesssim 0.15Re_{\tau }$ and are seen to reasonably follow wall scaling, that is, when the wavelengths are normalized by $z_{o}$. In contrast, no such collapse is observed when the wavelengths are scaled with $\delta$. It is noted that this behaviour is only apparent after separating ${\varPhi }_{a}$ from ${\varPhi }$. For comparison, figure 4 in § 5 shows the corresponding ${\varPhi }$ results which exhibit both $z_{o}$- and $\delta$-scaling in the intermediate- and large-scale wavelength ranges, respectively (due to the wall-parallel velocity field associated with both the active and inactive motions Bradshaw Reference Bradshaw1967; Baidya et al. Reference Baidya, Philip, Hutchins, Monty and Marusic2017).

Figure 3. (a,b) Constant energy contours for ${\varPhi }_{a}$($z^{+}_{o}$) at an energy level of 0.15 plotted for various $z^{+}_{o}$ as a function of wavelengths scaled with (a) $z_{o}$ and (b) $\delta$. Contours in red and blue correspond to ${\varPhi }_{a}$ estimated for the experimental and DNS datasets respectively (table 1), with dark to light shading indicating an increase in $z^{+}_{o}$ following $100 \lesssim z^{+}_{o} \lesssim 0.15{Re_{\tau }}$ for $Re_{\tau }$ corresponding to respective datasets. Dashed green lines represent the linear relationship, ${\lambda }_{x} = 3{\lambda }_{y}$. Panels (c,d) show ${\varPhi }_{a}$($z^{+}_{o}$) integrated across ${\lambda }_{y}$ and ${\lambda }_{x}$ to obtain its corresponding 1-D version as a function of (c) ${\lambda }_{x}$ and (d) ${\lambda }_{y}$ respectively, each plotted with wavelengths scaled by $z_{o}$. Same colour coding is followed as that described for (a,b). (e,f) Pre-multiplied streamwise 1-D cospectra/spectra for the (e) Reynolds shear stress and (f) wall-normal velocity plotted as a function of ${\lambda }_{x}$ scaled with $z_{o}$. These data are from the $Re_{\tau } \approx 10\,000$ dataset of Baidya et al. (Reference Baidya, Philip, Hutchins, Monty and Marusic2017) for various $z^{+}_{o}$. Dark to light shading corresponds to the increase in $z^{+}_{o}$ following $100 \lesssim z^{+}_{o}\lesssim 0.15{Re_{\tau }}$, where $Re_{\tau } \approx 10\,000$.

Figure 4. Constant energy contours for (a,b) ${\varPhi }$($z^{+}_{o}$) and (c,d) ${\varPhi }_{ia}$($z^{+}_{o}$) at energy level of 0.15 plotted for various $z^{+}_{o}$ as a function of wavelengths scaled with (a,c) $z_{o}$ and (b,d) $\delta$, respectively. All data in (ad) correspond to the high $Re_{\tau }$ experimental dataset reported in table 1, with dark to light shading indicating an increase in $z^{+}_{o}$ following $100 \lesssim z^{+}_{o}\lesssim 0.15{Re_{\tau }}$. Dashed green lines represent the linear relationship, ${\lambda }_{y}\sim {\lambda }_{x}$.

The $z_{o}$-scaling behaviour noted for ${\varPhi }_{a}$ is consistent with active motions. This can be seen by comparing the scaling behaviour of 1-D $w$-spectra and 1-D $uw$-cospectra, which have been shown to follow wall scaling and exhibit a behaviour exclusively associated with active motions (Bradshaw Reference Bradshaw1967; Morrison et al. Reference Morrison, Subramanian and Bradshaw1992; Baidya et al. Reference Baidya, Philip, Hutchins, Monty and Marusic2017). To this end, ${\varPhi }_{a}$ is integrated along ${\lambda }_{y}$ and ${\lambda }_{x}$ to obtain the corresponding premultiplied 1-D spectra as a function of ${\lambda }_{x}$ (${\varPhi }_{a,x}$; figure 3c) and ${\lambda }_{y}$ (${\varPhi }_{a,y}$; figure 3d), respectively. Also plotted are the pre-multiplied 1-D $w$-spectra (figure 3f) and $uw$-cospectra (figure 3e) at $100\lesssim z^{+}_{o}\lesssim 0.15Re_{\tau }$ from the $Re_{\tau }\approx 10\,000$ dataset of Baidya et al. (Reference Baidya, Philip, Hutchins, Monty and Marusic2017), measured at the same experimental facility as Deshpande et al. (Reference Deshpande, Chandran, Monty and Marusic2020a). When the wavelengths are scaled with $z_{o}$, the 1-D spectra in figure 3(cf) are observed to collapse for ${\lambda }\gtrsim {z_{o}}$, in line with the characteristics of active motions. Further, both ${\varPhi }_{a,x}$ and ${k^{+}_{x}}{{\phi }^{+}_{uw}}$ peak at ${\lambda }_{x}\sim 10z_{o}$, supporting the argument that the motions associated with ${\varPhi }_{a}$ contribute to the Reynolds shear stress and can hence be deemed active in the sense of Townsend (Reference Townsend1961, Reference Townsend1976). The efficacy of the present SLSE-based methodology in extracting energetic contributions from the active motions can also be tested by implementing it on similar two-point statistics computed for the $w$-velocity component. Given that the $w$-component is associated exclusively with the active motions (§ 1), the present methodology can be deemed effective if it reveals negligible energy contributions from the inactive spectrum for the $w$-component. Interested readers may refer to appendix A where the SLSE analysis conducted on the $w$-component has been discussed.

Small scales (${\lambda }\ll {z_{o}}$), which correspond to the viscous dissipative scales or those following the inertial sub-range scaling, do not scale with distance from the wall, explaining the deviation from the collapse of the 1-D spectra in figure 3(c,d,f). A similar deviation, although at a much smaller magnitude, is also observed for the Reynolds shear stress cospectra, which eventually drops to zero at ${{\lambda }_{x}}/{z_{o}}\lesssim 0.2$ owing to the approximate isotropy of these fine scales (Saddoughi & Veeravalli Reference Saddoughi and Veeravalli1994). On a side note, the reasonable agreement between ${\varPhi }_{a,x}$ estimated from the DNS and experimental datasets also validates the use of the local mean velocity as the convection velocity ($U_{c} = U(z_{o})$) for the active motions, which seems intuitive given these are localized at $z_{o}$.

The present analysis, which is conducted along both the $x$ and $y$ directions, also reveals the dominant spanwise wavelength corresponding to the active motions, i.e. ${\lambda }_{y}\sim 3{z_{o}}$ (figure 3d). This yields the dominant streamwise/spanwise aspect ratio of ${\lambda }_{x}$/${\lambda }_{y}\sim 3\text {--}4$ for these motions, which is found to be true across a decade of $Re_{\tau }$ (indicated by dashed line in figure 3a,b). A similar SLSE-based analysis, as implemented here for the $u$-velocity spectrum, was conducted on the DNS dataset to analyse the active component of the $v$- and $w$-velocity spectra (not shown here for brevity). These components were also found to exhibit wall scaling, across the inertially dominated region, with the contours of the spectrum following the self-similar relationship, ${\lambda }_{x}$/${\lambda }_{y}\sim 1$ and ${\lambda }_{x}$/${\lambda }_{y}\sim 1.4$ for the $v$ and $w$-velocity spectra, respectively (see Deshpande, Monty & Marusic Reference Deshpande, Monty, Marusic, Chanson and Brown2020b). Interestingly, the aspect ratio found for the active $u$-spectrum matches that of the self-similar wall-coherent vortex clusters (${\lambda }_{x}\sim 2\text {--}3{\lambda }_{y}$) investigated by del Álamo et al. (Reference del Álamo, Jiménez, Zandonade and Moser2006), Hwang (Reference Hwang2015) as well as very recently by Hwang, Lee & Sung (Reference Hwang, Lee and Sung2020), revealing information which may be useful for modelling the active motions in future works. The close agreement with Hwang (Reference Hwang2015) further suggests ${\varPhi }_{a}$ and ${\varPhi }_{ia}$, both of which comprise of prominent self-similar contributions (figures 2–4), correspond well with the two component attached eddy structure proposed by Hwang (Reference Hwang2015) for a wall-bounded turbulent flow. In their case, Hwang (Reference Hwang2015) defined motions at a given spanwise scale to be composed of two distinct components: the first is the long streaky flow structure, attached to the wall and having significant turbulent kinetic energy, but inactive in the inner region. The energy contributions from these motions are represented by ${\varPhi }_{ia}$. While the second component corresponds to the short and tall self-similar vortex packets which are active in the inner region, and hence would contribute to ${\varPhi }_{a}$.

5. Inactive component of the streamwise velocity spectrum

Figure 4 shows the constant energy contours of ${\varPhi }$ (figure 4a,b) and ${\varPhi }_{ia}$ (figure 4c,d), computed for the experimental dataset, plotted as a function of wavelengths scaled with $z_{o}$ (figure 4a,c) and $\delta$ (figure 4b,d). These contours are plotted at the same energy level and for the same $z^{+}_{o}$, as in figure 3(a,b). Consistent with the observations of Bradshaw (Reference Bradshaw1967) and Baidya et al. (Reference Baidya, Philip, Hutchins, Monty and Marusic2017) for the 1-D $u$-spectra, ${\varPhi }$ contours can be observed to be exhibiting $z_{o}$-scaling in the intermediate scales (${O}(1)\lesssim {\lambda }/{z_{o}} \lesssim {O}$(10)) and $\delta$-scaling for the large scales (${\lambda }\gtrsim {O}$($\delta$)). This is due to contributions from both the active as well as the inactive motions to ${\varPhi }$.

The parameter ${\varPhi }_{ia}$ also exhibits both $z_{o}$- and ${\delta }$-scaling, with the scale range for $z_{o}$-scaling, however, much narrower than that observed for ${\varPhi }$. This can be attributed to the fact that ${\varPhi }_{ia}$($z_{o}$) comprises contributions from the attached eddies of height, ${{O}}(z_{o})\ll {\mathcal {H}}\lesssim {{O}}(\delta )$, as well as the $\delta$-scaled SS (§§ 1,3). It means that the attached eddy contributions form a considerable portion of the total inactive contributions at any $z_{o}$ close to the wall, due to which a clear ${\lambda }_{y}\sim {\lambda }_{x}$ trend is discernible in ${\varPhi }_{ia}$($z_{o}$). Townsend (Reference Townsend1976), however, described the classification of an eddy as ‘active’ or ‘inactive’ to be a relative concept, dependent on the wall-normal location under consideration. Hence, the tall attached eddies which are inactive relative to $z^{+}_{o} \approx 100$ may qualify as active at greater wall heights. This explains the narrowing down of the ${\varPhi }_{ia}$($z_{o}$) contours to the largest scales with increase in $z^{+}_{o}$ (figure 4d), until only the superstructure contributions remain at $z^{+}_{o}\approx 0.15Re_{\tau }$. The latter explains the deviation of the contours from the linear relationship, as $z^{+}_{o}$ moves away from the wall.

The reduction in the attached eddy contributions, with increase in $z^{+}_{o}$, translates into a drop of the cumulative streamwise turbulence intensity, i.e. $\iint _{0}^{\infty } {{\varPhi }_{ia}} {{\,\textrm {d}(\ln {{\lambda }_{x}})}\,{\textrm {d}(\ln {{\lambda }_{y}})}}$, plotted in figure 5(b) for the experimental dataset. Also shown alongside in figure 5(a) are cumulative contributions obtained by integrating ${\varPhi }$ and ${\varPhi }_{a}$ for $100 \lesssim z^{+}_{o}\lesssim 0.15Re_{\tau }$. Figure 5 also includes, for reference, the well-resolved ${\overline {u^2}}^{+}$ profile of Samie et al. (Reference Samie, Marusic, Hutchins, Fu, Fan, Hultmark and Smits2018) across the entire boundary layer, as well as a log law with $A_{1}=0.98$ proposed by Baars & Marusic (Reference Baars and Marusic2020b). As is evident from the plot, the contributions from both ${\varPhi }$ and ${\varPhi }_{ia}$ decay with $z/{\delta }$ very similarly; however, they only approximately follow the $A_{1}=0.98$ log law. This disagreement can be associated with the $\delta$-scaled superstructure contributions existing in both $\varPhi$ and ${\varPhi }_{ia}$ (Jimenez & Hoyas Reference Jimenez and Hoyas2008; Baars & Marusic Reference Baars and Marusic2020b), given that the expressions in (1.1) are valid strictly for self-similar attached eddy contributions alone ($\S$1). An attempt is thus made to remove this superstructure contribution from ${\varPhi }_{ia}$ in the next sub-section, by following the same SLSE-based methodology discussed previously in $\S$3. Returning to figure 5, a similar variation for both the profiles obtained on integrating $\varPhi$ and ${\varPhi }_{ia}$ leads to the cumulative energy contributions from ${\varPhi }_{a}$ (${\approx }2.7$) being nearly constant across the inertial region (figure 5a). Such a trend is consistent with the statistical properties of the active motions scaling universally with $U_{\tau }$ and $z$ (Townsend Reference Townsend1961; Bradshaw Reference Bradshaw1967).

Figure 5. Comparison of the normalized streamwise turbulence intensities obtained by integrating ${\varPhi }$ (${=}{\overline {u^2}}^{+}$), ${\varPhi }_{a}$ (${\approx }\overline {u^{2}}^{+}_\textit {active}$), ${\varPhi }_{ia}$ (${\approx }\overline {u^{2}}^{+}_\textit {inactive}$) and ${\varPhi }^{AE}_{ia}$ (${\approx }\overline {u^{2}}^{+}_\textit {inactive, AE}$) for the high $Re_{\tau }$ experimental dataset described in table 1. Also plotted for comparison is the well-resolved ${\overline {u^2}}^{+}$ measured by Samie et al. (Reference Samie, Marusic, Hutchins, Fu, Fan, Hultmark and Smits2018) across a ZPG TBL maintained at an $Re_{\tau }$ comparable to the present experimental dataset. The dashed green line in (b) represents the logarithmic decay of ${\overline {u^2}}^{+}$ described by (1.1) with $A_{1}=0.98$ (Baars & Marusic Reference Baars and Marusic2020b), while the dash-dotted golden line in (a) represents a constant ${\overline {u^2}}^{+} = 2.7$.

5.1. Inactive contributions from the self-similar attached eddies

Here, we consider isolating the inactive contributions from the self-similar attached eddies, by first estimating the $\delta$-scaled superstructure contributions to ${\varPhi }$($z_{o}$). As discussed previously in § 1 and observed from the experimental data in figures 2 and 4, the SS extend from the wall and span across the entire inertial region, while contribution from the tallest attached eddies is insignificant beyond the upper bound of the log region ($z^+\sim 0.15Re_{\tau }$). This is supported by the scale-by-scale coupling (${\varPhi }_{cross}$) computed from the $u$-signals simultaneously measured at $z^{+}_{o}$ (${\approx }100, 200$ or 318) and $z^{+}_{r}\approx 0.15Re_{\tau }$ plotted in figure 6(a), where the energy contours can be seen to be restricted only to the very-large-scale end of ${\varPhi }$, indicative of the superstructure signature. The choice of $z^{+}_{r} \approx 0.15Re_{\tau }$ is also consistent with Baars & Marusic (Reference Baars and Marusic2020a,Reference Baars and Marusicb), who also used it as a reference location to extract the superstructure contribution. They recommended keeping $z^{+}_{o}\lesssim {z^{+}_{r}}/8$ to meet the requirement of $z^{+}_{r} \gg z^{+}_{o}$, which explains the present ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 0.15Re_{\tau }$) measurements conducted at only three wall-normal locations ($z^{+}_{o}$) in the inertially dominated region. It is worth noting here that, owing to this condition, the cross-spectrum analysis to isolate the superstructure contribution is only possible on the high $Re_{\tau }$ experimental dataset. On computing ${\varPhi }_{cross}$($z^{+}_{o},z^{+}_{r}\approx 0.15Re_{\tau }$) from the experimental data, it is used in conjunction with the SLSE (appendix A) to obtain a linear stochastic estimate of the spectrum (${\varPhi }^{SS}_{ia}$) associated with the superstructure contributions at $z_{o}$ following

(5.1)\begin{equation} {{{\varPhi}^{SS}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})} = {\frac{{\left[{{\varPhi}_{cross}}({z^{+}_{o}}, {z^{+}_{r}} \approx 0.15{Re_{\tau}};{\lambda_{x}},{\lambda_{y}}) \right]}^{2} }{ {{\varPhi}}({z^{+}_{r}} \approx 0.15{Re_{\tau}};{\lambda_{x}},{\lambda_{y}}) } }. \end{equation}

The above expression is similar to (3.1) discussed in § 3, with the calculations in (5.1) also carried out first in the frequency domain, followed by the conversion to ${\lambda }_{x}$ done by invoking Taylor's hypothesis using $U_{c}= U(z^{+}_{r}\approx 0.15Re_{\tau })$ (Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb). The choice of $U_{c}$ in (5.1) is based on the ‘global’ nature and high convection speeds of the $\delta$-scaled SS (Jimenez & Hoyas Reference Jimenez and Hoyas2008; del Álamo & Jiménez Reference del Álamo and Jiménez2009; Monty & Chong Reference Monty and Chong2009).

Figure 6. (a) Constant energy contours for ${\varPhi }$($z^{+}_{o}$), ${\varPhi }_{cross}$($z^{+}_{o}$, $z^{+}_{r}\approx 0.15{Re_{\tau }}$) and ${\varPhi }$($z^{+}_{r}\approx 0.15Re_{\tau }$) at an energy level of 0.15 plotted for $z^{+}_{o}\approx 100$ and 318. (b) Constant energy contours for ${\varPhi }^{AE}_{ia}$($z^{+}_{o}$) and ${\varPhi }^{SS}_{ia}$($z^{+}_{o}$), computed via (5.1) and (5.2), plotted at the same energy level and $z^{+}_{o}$ as in (a). All contours in (a,b) are computed from the high $Re_{\tau }$ experimental data. Dashed green lines represent the linear relationship, ${\lambda }_{y}\sim {\lambda }_{x}$.

Contours associated with all the energy spectra in (5.1) have been plotted in figure 6(b), with ${\varPhi }^{SS}_{ia}$ centred around a $\delta$-scaled location of ${\lambda }_{x}\sim 7\delta$, ${\lambda }_{y}\sim 0.7\delta$, representative of the SS. Following the linear superposition assumption in (1.4), ${\varPhi }^{SS}_{ia}$($z_{o}$) can be simply subtracted from ${\varPhi }_{ia}$($z_{o}$) to estimate the inactive contributions from the attached eddies at $z_{o}$ (${\varPhi }^{AE}_{ia}$)

(5.2)\begin{equation} {{{\varPhi}^{AE}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})} = {{{\varPhi}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})} - {{{\varPhi}^{SS}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}})}, \end{equation}

with ${\varPhi }^{SS}_{ia}$ and ${\varPhi }^{AE}_{ia}$ representative of $\overline {u^{2}}^{+}_\textit {inactive,SS}$ and $\overline {u^{2}}^{+}_\textit {inactive,AE}$, respectively. The claim is also supported by the ${\varPhi }^{AE}_{ia}$ contours plotted in figure 6(b), which are seen to follow the ${\lambda }_{y}\sim {\lambda }_{x}$ relationship representing geometric self-similarity. The parameter $\overline {u^{2}}^{+}_\textit {inactive,AE}$, obtained via integrating ${\varPhi }^{AE}_{ia}$ at the three $z^{+}_{o}$, has also been plotted in figure 5(b). While the trend looks promising when compared with the ${\overline {u^2}}^{+}$ expression in (1.1), three data points are not sufficient to firmly establish the present claim (for this, additional data at even higher Reynolds number would be required). However, to confirm the association of ${\varPhi }^{AE}_{ia}$ with pure attached eddy contributions, we check for the constant energy plateau (representative of the $k^{-1}_{x}$-scaling) in the corresponding premultiplied 1-D spectra. In this respect, the parameters in the present analysis align well with the necessary conditions proposed by Perry & Chong (Reference Perry and Chong1982) and Nickels et al. (Reference Nickels, Marusic, Hafez and Chong2005) to observe a clear $k^{-1}_{x}$ region, i.e. to measure sufficiently close to the wall in a high $Re_{\tau }$ wall-bounded flow.

To this end, ${\varPhi }^{AE}_{ia}$ is integrated along ${\lambda }_{y}$ and ${\lambda }_{x}$ to obtain the corresponding premultiplied 1-D spectra as a function of ${\lambda }_{x}$ (${\varPhi }^{AE}_{ia,x}$) and ${\lambda }_{y}$ (${\varPhi }^{AE}_{ia,y}$), respectively, which has been plotted for the three $z^{+}_{o}$ in figure 7. Also plotted for reference in the same figure are the premultiplied 1-D spectra (${\varPhi }_{x}$, ${\varPhi }_{y}$) obtained by integrating ${\varPhi }$ in the same manner. Indeed, ${\varPhi }^{AE}_{ia,x}$ can be observed to be plateauing at $A_{1x}\approx 0.98$ (nominally) for all three $z^{+}_{o}$, which is consistent with the Townsend–Perry constant ($A_{1}$) estimated by Baars & Marusic (Reference Baars and Marusic2020b) from the streamwise turbulence intensity profile. The span of the ${\varPhi }^{AE}_{ia,x}$ plateau, however, shrinks in size with the increase in $z^{+}_{o}$, likely due to decrease in the hierarchy of attached eddies inactive at $z_{o}$ (Perry & Chong Reference Perry and Chong1982). To the best of the authors’ knowledge, the present result is the first empirical evidence that establishes consistency between the logarithmic decay rate of the streamwise turbulence intensity and the constant energy plateau from the premultiplied 1-D $u$-spectrum, as argued by Perry et al. (Reference Perry, Henbest and Chong1986) in the case of pure attached eddy contributions. This consistency, however, was not observed in the recent effort by Baars & Marusic (Reference Baars and Marusic2020a,Reference Baars and Marusicb) due to the energy decomposition conducted directly for the 1-D $u$-spectra in their case. That analysis neglected the scale-specific coherence over the spanwise direction, which has been duly considered in the present study using the new experimental data.

Figure 7. Values of ${\varPhi }$($z^{+}_{o}$) and ${\varPhi }^{AE}_{ia}$($z^{+}_{o}$) integrated across ${\lambda }_{y}$ and ${\lambda }_{x}$ to obtain their corresponding premultiplied 1-D version as a function of ${\lambda }_{x}$ (${\varPhi }_{x}$, ${\varPhi }^{AE}_{ia,x}$; solid line) and ${\lambda }_{y}$ (${\varPhi }_{y}$, ${\varPhi }^{AE}_{ia,y}$; dash-dotted line), respectively, for $z^{+}_{o}\approx$ (a) 100, (a) 200 and (c) 318. Also highlighted are the peaks/plateaus of ${\varPhi }^{AE}_{ia,x}$ and ${\varPhi }^{AE}_{ia,y}$ ($A_{1x}$, $A_{1y}$), along with those of ${\varPhi }_{x}$ and ${\varPhi }_{y}$ ($A'_{1x}$, $A'_{1y}$).

The present analysis also reveals the plateau, $A_{1y}$ in the premultiplied spanwise 1-D spectra (${\varPhi }^{AE}_{ia,y}$), which is found to be nominally equal to $A_{1x}$ for all $z^{+}_{o}$. The equality $A_{1y} \approx A_{1x}$ obtained here, thus satisfies the necessary condition proposed by Chandran et al. (Reference Chandran, Baidya, Monty and Marusic2017) to associate the 2-D spectrum, ${\varPhi }^{AE}_{ia}$ with purely self-similar contributions. This condition was also recently confirmed by Hwang et al. (Reference Hwang, Lee and Sung2020), by conducting a spectral analysis of the wall-coherent self-similar $u$-structures extracted from low-$Re_{\tau }$ DNS simulations. The value of ${\varPhi }_{y}$ is also observed to have a plateau at $A'_{1y}\approx 1.3$ (at $z^{+}_{o}\approx 100$), a value which is consistent with that reported by Lee & Moser (Reference Lee and Moser2015). However, $A'_{1y}\neq A'_{1x}$, with both values changing as a function of $z^{+}_{o}$. This behaviour can be associated with the non-self-similar contributions in $\varPhi$ obscuring the pure self-similar characteristics, which have been successfully isolated in the present study in the form of ${\varPhi }^{AE}_{ia}$.

6. Concluding remarks

The present study proposes a methodology to extract the $u$-energy spectrum associated with the active and inactive motions (Townsend Reference Townsend1961, Reference Townsend1976) coexisting at any $z_{o}$ in the inertially dominated region of a wall-bounded flow. The methodology is based on isolating the streamwise turbulent energy associated with the inactive motions from the total energy, based on their known characteristic of being larger than the coexisting active motions and coherent across a substantial wall-normal range (Townsend Reference Townsend1961, Reference Townsend1976). This is tested using ZPG TBL datasets comprising two-point $u$-signals, synchronously acquired at $z_{o}$ and a near-wall location ($z_{r}$), such that $z_{r}\ll z_{o}$. The velocity–velocity coupling, constructed by cross-correlating these $u$-signals, is fed into an SLSE-based procedure which linearly decomposes the full 2-D spectrum $\varPhi$($z_{o}$) into components representative of the active (${\varPhi }_{a}$) and inactive (${\varPhi }_{ia}$) motions at $z_{o}$.

The parameter ${\varPhi }_{a}$ is found to exhibit $z_{o}$-scaling across a decade of $Re_{\tau }$, and is also consistent with the characteristics depicted by the Reynolds shear stress cospectra, thereby confirming the association of ${\varPhi }_{a}$ with the active motions. Analysis conducted across both spatially (DNS) and temporally resolved (experimental) datasets also confirms the validity of Taylor's hypothesis for the active motions. Further, decomposition of ${\varPhi }$ into ${\varPhi }_{a}$ and ${\varPhi }_{ia}$ brings out the self-similar characteristic of the two spectra, which is consistent with Townsend's hypothesis on both active and inactive motions essentially being associated with contributions from the attached eddies, but of different sizes.

While ${\varPhi }_{a}$($z_{o}$) is found to be associated predominantly with the self-similar attached eddies of height $\mathcal {H}$ $\sim$ ${O}(z_{o})$, ${\varPhi }_{ia}$($z_{o}$) is found to have contributions from both, the relatively tall self-similar attached eddies (${O}(z_{o})\ll \mathcal {H}\lesssim {O}(\delta )$) as well as the large $\delta$-scaled eddies associated with the SS. The latter is confirmed by the reduced self-similar contributions to ${\varPhi }_{ia}$ with increasing $z_{o}$, due to the large attached eddies qualifying as active in accordance with the original concept given by Townsend (Reference Townsend1961, Reference Townsend1976). The present study also segregates the inactive contributions from the attached eddies (${\varPhi }^{AE}_{ia}$), from those coming from the $\delta$-scaled SS (${\varPhi }^{SS}_{ia}$), by utilizing the same SLSE-based methodology used earlier. The estimation of ${\varPhi }^{AE}_{ia}$ reveals the constant energy plateau, representative of $k^{-1}$-scaling, in the corresponding premultiplied streamwise and spanwise 1-D $u$-spectra. Both these spectra were found to plateau at $A_{1}\approx 0.98$ (nominally), yielding the first empirical evidence to establish the consistency with $A_{1}$ obtained from the streamwise turbulence intensity profiles (Baars & Marusic Reference Baars and Marusic2020b), as argued by Perry & Chong (Reference Perry and Chong1982) for the case of pure attached eddy contributions.

Acknowledgements

The authors are thankful to the authors of Sillero et al. (Reference Sillero, Jiménez and Moser2014) and Baidya et al. (Reference Baidya, Philip, Hutchins, Monty and Marusic2017) for making their respective data available. The authors also thank Dr D. Chandran for assistance with the experiments, and Dr W. J. Baars and Dr A. Madhusudanan for helpful discussions related to SLSE. The authors are also grateful to the anonymous reviewers for their helpful comments which significantly improved the quality of the manuscript.

Funding

The authors wish to acknowledge the Australian Research Council for financial support.

Declaration of interests

The authors report no conflict of interest.

Appendix A. SLSE methodology adopted for energy decomposition

Here, we demonstrate the methodology to estimate a component of the full $u$-energy spectrum at $z_{o}$, comprising contributions from specific coherent motions coexisting at $z_{o}$, via the SLSE approach. The procedure has been adopted from previous studies in the literature employing SLSE (Tinney et al. Reference Tinney, Coiffet, Delville, Hall, Jordan and Glauser2006; Baars et al. Reference Baars, Hutchins and Marusic2016; Encinar & Jiménez Reference Encinar and Jiménez2019; Madhusudanan, Illingworth & Marusic Reference Madhusudanan, Illingworth and Marusic2019), which may be referred to for further understanding on this topic. The SLSE considers a scale-specific unconditional input (at $z_{r}$) to give a scale-specific conditional output (at $z_{o}$) following

(A 1)\begin{equation} {\tilde{u}}^{E}(z_{o};{\lambda_{x}},{\lambda_{y}}) = {{H_{L}}(z_{o},z_{r}; {\lambda_{x}},{\lambda_{y}})}\tilde{u}(z_{r};{\lambda_{x}},{\lambda_{y}}), \end{equation}

where ${\tilde {u}}(z_{r};{\lambda _{x}},{\lambda _{y}})$ is the 2-D Fourier transform of $u({z_{r}})$ in $x$ and $y$. Here, the superscript $E$ represents the estimated quantity and $H_{L}$ represents the scale-specific linear transfer kernel. It should be noted that the SLSE approach enables accurate estimation of only those scales (at $z_{o}$) that are coherent across $z_{o}$ and $z_{r}$. Equation (A 1) can be further used to estimate the 2-D energy spectrum, ${\varPhi }^{E}$ at $z_{o}$ (Madhusudanan et al. Reference Madhusudanan, Illingworth and Marusic2019) following

(A 2)\begin{equation} {{\varPhi}^{E}}(z_{o};{\lambda_{x}},{\lambda_{y}}) = {{|{H_{L}}(z_{o},{z_{r}}; {\lambda_{x}},{\lambda_{y}})|}^{2}}{{\varPhi}({z_{r}};{\lambda_{x}},{\lambda_{y}})}. \end{equation}

To obtain $u^{E}$ and ${\varPhi }^{E}$ at $z_{o}$, the transfer kernel $H_{L}$ is required to be computed from an ensemble of data following

(A 3)\begin{align} {H_{L}}(z_{o},z_{r};{\lambda_{x}},{\lambda_{y}}) &= \frac{ {\langle \tilde{u}(z_{o};{\lambda_{x}},{\lambda_{y}}){{\tilde{u}}^{\ast}} (z_{r};{\lambda_{x}},{\lambda_{y}}) \rangle} }{ {\langle {\tilde{u}(z_{r}; {\lambda_{x}},{\lambda_{y}})}{{\tilde{u}}^{\ast}(z_{r};{\lambda_{x}},{\lambda_{y}})} \rangle} } \nonumber\\ &= {|{{H_{L}}(z_{o},z_{r};{\lambda_{x}},{\lambda_{y}})}|}{\exp({i{\psi}(z_{o},z_{r};{\lambda_{x}},{\lambda_{y}})})}, \end{align}

with ${| {H_{L}} |}$ and $\psi$ the scale-specific gain and phase respectively, and the asterisk ($\ast$), angle brackets ($\langle \rangle$) and vertical bars ($||$) denoting the complex conjugate, ensemble averaging and modulus, respectively. Considering $z^{+}_{r}$ as the reference wall-normal location used in the present study, ${| {H_{L}} |}$ from (A 3) can be simply expressed as a function of the two types of 2-D spectra computed from the multi-point datasets (refer $\S$2) at various $z^{+}_{o}$ in the inertial region following

(A 4)\begin{equation} {| {{H_{L}}(z^{+}_{o},{z^{+}_{r}};{\lambda_{x}},{\lambda_{y}})} |} = \frac{{{\varPhi}_{cross}}({z^{+}_{o}},{z^{+}_{r}};{\lambda_{x}}, {\lambda_{y}})}{{\varPhi}({z^{+}_{r}};{\lambda_{x}},{\lambda_{y}})}. \end{equation}

In the case of $z^{+}_{r}$ $\ll$ $z^{+}_{o}$, ${{{\varPhi }^{E}}(z_{o};{\lambda _{x}},{\lambda _{y}})}$ would be representative of the energy contributions from all coexisting motions taller than $z_{o}$, which as per our discussion in § 3 leads to ${{{{\varPhi }^{E}}(z_{o};{\lambda _{x}},{\lambda _{y}})}{{|}_{{z^{+}_{r}} \approx 15}}}{\rightarrow }{{\varPhi }_{ia}}(z_{o};{\lambda _{x}},{\lambda _{y}})$. A simplified expression for ${\varPhi }_{ia}$ can be deduced from (A 2) and (A 4) as follows:

(A 5)\begin{align} {{\varPhi}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}}) &= {{| {H_{L}}(z^{+}_{o},{z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}}) |}^{2}}{{{\varPhi}}({z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}})} \nonumber\\ &= { \frac{ {\left[{{\varPhi}_{cross}}({z^{+}_{o}},{z^{+}_{r}} {\approx} 15;{\lambda_{x}},{\lambda_{y}}) \right]}^{2} }{ {{\varPhi}}({z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}}) } }. \end{align}

Similarly, in case of $z^{+}_{r}\gg z^{+}_{o}$, ${{{\varPhi }^{E}}(z_{o};{\lambda _{x}},{\lambda _{y}})}$ would be representative of the energy contributions from all coexisting motions at $z_{o}$ that are taller than $z_{r}$, which as per our discussion in § 5.1 leads to ${{{{\varPhi }^{E}}(z_{o};{\lambda _{x}},{\lambda _{y}})}{{|}_{{z^{+}_{r}} \approx 0.15Re_{\tau }}}}{\rightarrow } {{\varPhi }^{SS}_{ia}}(z_{o};{\lambda _{x}},{\lambda _{y}})$, and can be estimated following

(A 6)\begin{equation} {{\varPhi}^{SS}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}}) = {\frac{{\left[{{\varPhi}_{cross}}({z^{+}_{o}},{z^{+}_{r}} \approx 0.15{Re_{\tau}};{\lambda_{x}},{\lambda_{y}}) \right]}^{2} }{ {{\varPhi}}({z^{+}_{r}} \approx 0.15Re_{\tau};{\lambda_{x}},{\lambda_{y}}) } }. \end{equation}

Availability of both the numerator and denominator in the above expressions (table 1) allows direct computation of ${\varPhi }_{ia}$ and ${\varPhi }^{SS}_{ia}$, without separately estimating ${| H_{L} |}^2$, for both the datasets. It should be noted here that ${\varPhi }_{ia}$ is computed in the frequency domain for the experimental dataset, with the conversion to ${\lambda }_{x}$ obtained by invoking Taylor's hypothesis, using $U_{c}=U$($z_{o}$) (Baars et al. Reference Baars, Hutchins and Marusic2016, Reference Baars, Hutchins and Marusic2017). The value of ${\varPhi }^{SS}_{ia}$ is also computed in the similar manner, however, with the conversion to ${\lambda }_{x}$ achieved by using $U_{c}=U$($z^{+}_{r}\approx 0.15Re_{\tau }$) (Baars & Marusic Reference Baars and Marusic2020a,Reference Baars and Marusicb).

As can be noted from (A 5), the essential information on energetic motions coherent across $z_{o}$ and $z_{r}$ is embedded in ${| H_{L} |}^2$ which is translated into ${\varPhi }_{ia}$ (or ${\varPhi }^{SS}_{ia}$) via scale-by-scale amplification/attenuation provided by ${\varPhi }$($z^{+}_{r}$). For example, figure 8(a) shows ${| {H_{L}}(z^{+}_{o},{z^{+}_{r}} {\approx } 15) |}^2$ computed from the DNS dataset at various $z^{+}_{o}$ listed in table 1, along with ${\varPhi }$($z^{+}_{r}\approx 15$) for the same dataset. It is evident from the plot that ${|{H_{L}}(z^{+}_{o} {\approx } 100,{z^{+}_{r}} {\approx } 15)|}^2$ contours conform predominantly to the large scales of the spectrum, with the contours moving very gradually to even larger scales with increase in $z^{+}_{o}$. This explains the observation noted in § 3 on ${\varPhi }_{ia}$ and ${\varPhi }_{a}$ respectively taking up the higher and lower ends of the full spectrum, ${\varPhi }$($z_{o}$).

Figure 8. Contours for the linear transfer kernel (black), for $z^{+}_{r} \approx 15$, and the near-wall 2-D spectra (magenta) for the (a) $u$- and (b) $w$-velocity components. Here, the transfer kernels are computed at various $z^{+}_{o}$ from the DNS dataset of Sillero et al. (Reference Sillero, Jiménez and Moser2014), described in table 1. Dark to light shading indicates an increase in $z^{+}_{o}$ following $100\lesssim z^{+}_{o}\lesssim 0.15Re_{\tau }$. The contour levels for the transfer kernels, ${| H_{L} |}^2$ and ${| G_{L} |}^2$ correspond to approximately 10 % of the maximum value recorded for the kernel at the respective $z^{+}_{o}$, while that for ${\varPsi }$($z^{+}_{r}\approx 15$) has intentionally been kept very low to highlight no overlap with the associated transfer kernel, ${| G_{L} |}^2$.

We also use this opportunity to test the efficacy of the SLSE-based methodology, used here to estimate energy contributions from the active motions. To this end, the same procedure as that outlined in (A 1)–(A 5), is implemented on the wall-parallel $w$-velocity fields also retrieved from the DNS dataset, at the same $z^{+}_{o}$ and $z^{+}_{r}$ as that selected for the $u$-velocity field (table 1). The $w$-velocity fields are used to compute the two types of 2-D spectra, computed previously for the $u$-component, at the same $z^{+}_{o}$ in the inertial region following

(A 7)\begin{equation} \left.\begin{aligned} {\varPsi}(z^{+}_{o};{{\lambda}_{x}},{{\lambda}_{y}}) & = {|}{k^{+}_{x}}{k^{+}_{y}} {{\phi}^{+}_{{w_{o}}{w_{o}}}}({z^{+}_{o}};{{\lambda}_{x}},{{\lambda}_{y}}){|} \quad \text{and}\\ {{\varPsi}_{cross}}(z^{+}_{o},{z^{+}_{r}} {\approx} 15;{{\lambda}_{x}},{{\lambda}_{y}}) & = {|}{k^{+}_{x}}{k^{+}_{y}}{{\phi}^{+}_{{w_{o}}{w_{r}}}}({z^{+}_{o}},{z^{+}_{r}} {\approx}15;{{\lambda}_{x}},{{\lambda}_{y}}){|}, \end{aligned}\right\} \end{equation}

where (A 7) is analogous to (2.3) expressed for the $u$-component. Similarly, the inactive component ${\varPsi }_{ia}$ of the $w$-velocity field can be computed via an expression similar to (A 5) given previously for the $u$-component

(A 8)\begin{equation} \left.\begin{aligned} {{\varPsi}_{ia}}(z^{+}_{o};{\lambda_{x}},{\lambda_{y}}) & = {{| {G_{L}}(z^{+}_{o},{z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}}) |}^{2}}{{{\varPsi}}({z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}})},\quad \text{where}\\ {| {{G_{L}}(z^{+}_{o},{z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}})} |} & = \frac{{{\varPsi}_{cross}}({z^{+}_{o}},{z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}})}{{\varPsi} ({z^{+}_{r}} \approx 15;{\lambda_{x}},{\lambda_{y}})}. \end{aligned}\right\} \end{equation}

Accordingly, ${\varPsi }_{a}(z_{o}) ={\varPsi }$($z_{o}$) – ${\varPsi }_{ia}$($z_{o}$). Given the fact that the $w$-component is predominantly associated with the active motions (Bradshaw Reference Bradshaw1967; Morrison et al. Reference Morrison, Subramanian and Bradshaw1992; Baidya et al. Reference Baidya, Philip, Hutchins, Monty and Marusic2017), i.e. ${\varPsi }_{a}(z_{o}) \approx \varPsi$($z_{o}$), we would expect the SLSE procedure to reveal cumulative energy contributions from ${\varPsi }_{ia}$ to be negligible. This is possible if ${{| {G_{L}} |}^2}$ and ${\varPsi }$($z^{+}_{r} \approx 15$) do not overlap at common scales (as per (A 8)). Figure 8(b) shows ${{| {G_{L}} |}^2}$ contours computed for various $z^{+}_{o}$ from the DNS dataset alongside ${\varPsi }$($z^{+}_{r}\approx 15$), clearly suggesting an insignificant overlap between the two. Accordingly, ${\varPsi }_{ia}(z_{o}) \approx 0$ in the inertial region leading to ${\varPsi }_{a}(z_{o})\approx {\varPsi }$($z_{o}$), which proves the effectiveness of the SLSE-based methodology in extracting the energy spectrum associated with the active motions.

References

del Álamo, J.C. & Jiménez, J. 2009 Estimation of turbulent convection velocities and corrections to Taylor's approximation. J. Fluid Mech. 640, 526.CrossRefGoogle Scholar
del Álamo, J.C., Jiménez, J., Zandonade, P. & Moser, R.D. 2006 Self-similar vortex clusters in the turbulent logarithmic region. J. Fluid Mech. 561, 329358.CrossRefGoogle Scholar
Baars, W.J., Hutchins, N. & Marusic, I. 2016 Spectral stochastic estimation of high-Reynolds-number wall-bounded turbulence for a refined inner-outer interaction model. Phys. Rev. Fluids 1 (5), 054406.CrossRefGoogle Scholar
Baars, W.J., Hutchins, N. & Marusic, I. 2017 Self-similarity of wall-attached turbulence in boundary layers. J. Fluid Mech. 823, R2.CrossRefGoogle Scholar
Baars, W.J. & Marusic, I. 2020 a Data-driven decomposition of the streamwise turbulence kinetic energy in boundary layers. Part 1. Energy spectra. J. Fluid Mech. 882, A25.CrossRefGoogle Scholar
Baars, W.J. & Marusic, I. 2020 b Data-driven decomposition of the streamwise turbulence kinetic energy in boundary layers. Part 2. Integrated energy and ${A_{1}}$. J. Fluid Mech. 882, A26.CrossRefGoogle Scholar
Baidya, R., Philip, J., Hutchins, N., Monty, J.P. & Marusic, I. 2017 Distance-from-the-wall scaling of turbulent motions in wall-bounded flows. Phys. Fluids 29 (2), 020712.CrossRefGoogle Scholar
Baidya, R., Philip, J., Monty, J.P., Hutchins, N. & Marusic, I. 2014 Comparisons of turbulence stresses from experiments against the attached eddy hypothesis in boundary layers. In Proceedings of 19th Australasian Fluid Mechanics Conference.Google Scholar
Balakumar, B.J. & Adrian, R.J. 2007 Large-and very-large-scale motions in channel and boundary-layer flows. Phil. Trans. R. Soc. Lond. A 365 (1852), 665681.Google ScholarPubMed
Bradshaw, P. 1967 ‘Inactive’ motion and pressure fluctuations in turbulent boundary layers. J. Fluid Mech. 30 (2), 241258.CrossRefGoogle Scholar
Chandran, D., Baidya, R., Monty, J.P. & Marusic, I. 2017 Two-dimensional energy spectra in high-Reynolds-number turbulent boundary layers. J. Fluid Mech. 826, R1.CrossRefGoogle Scholar
Chandran, D., Monty, J.P. & Marusic, I. 2020 Spectral-scaling-based extension to the attached eddy model of wall turbulence. Phys. Rev. Fluids 5 (10), 104606.CrossRefGoogle Scholar
Chernyshenko, S.I., Marusic, I. & Mathis, R. 2012 Quasi-steady description of modulation effects in wall turbulence. arXiv:1203.3714.Google Scholar
Chin, C.C., Hutchins, N., Ooi, A.S.H. & Marusic, I. 2009 Use of direct numerical simulation (DNS) data to investigate spatial resolution issues in measurements of wall-bounded turbulence. Meas. Sci. Technol. 20 (11), 115401.CrossRefGoogle Scholar
Deshpande, R., Chandran, D., Monty, J.P. & Marusic, I. 2020 a Two-dimensional cross-spectrum of the streamwise velocity in turbulent boundary layers. J. Fluid Mech. 890, R2.CrossRefGoogle Scholar
Deshpande, R., Monty, J.P. & Marusic, I. 2019 Streamwise inclination angle of large wall-attached structures in turbulent boundary layers. J. Fluid Mech. 877, R4.CrossRefGoogle Scholar
Deshpande, R., Monty, J.P. & Marusic, I. 2020 b Active and inactive motions in wall turbulence. In Proceedings of 22nd Australasian Fluid Mechanics Conference (ed. Chanson, H & Brown, R.). The University of Queensland.CrossRefGoogle Scholar
Encinar, M.P. & Jiménez, J. 2019 Logarithmic-layer turbulence: A view from the wall. Phys. Rev. Fluids 4 (11), 114603.CrossRefGoogle Scholar
Ganapathisubramani, B., Hutchins, N., Hambleton, W.T., Longmire, E.K. & Marusic, I. 2005 Investigation of large-scale coherence in a turbulent boundary layer using two-point correlations. J. Fluid Mech. 524, 5780.CrossRefGoogle Scholar
Guezennec, Y.G. 1989 Stochastic estimation of coherent structures in turbulent boundary layers. Phys. Fluids A 1 (6), 10541060.CrossRefGoogle Scholar
Hultmark, M., Vallikivi, M., Bailey, S.C.C. & Smits, A.J. 2012 Turbulent pipe flow at extreme Reynolds numbers. Phys. Rev. Lett. 108 (9), 094501.CrossRefGoogle ScholarPubMed
Hutchins, N. & Marusic, I. 2007 Evidence of very long meandering features in the logarithmic region of turbulent boundary layers. J. Fluid Mech. 579, 128.CrossRefGoogle Scholar
Hutchins, N., Nickels, T.B., Marusic, I. & Chong, M.S. 2009 Hot-wire spatial resolution issues in wall-bounded turbulence. J. Fluid Mech. 635, 103136.CrossRefGoogle Scholar
Hwang, J., Lee, J.H. & Sung, H.J. 2020 Statistical behaviour of self-similar structures in canonical wall turbulence. J. Fluid Mech. (in press).CrossRefGoogle Scholar
Hwang, Y. 2015 Statistical structure of self-sustaining attached eddies in turbulent channel flow. J. Fluid Mech. 767, 254289.CrossRefGoogle Scholar
Jimenez, J. & Hoyas, S. 2008 Turbulent fluctuations above the buffer layer of wall-bounded flows. J. Fluid Mech. 611, 215236.CrossRefGoogle Scholar
Jones, M.B., Marusic, I. & Perry, A.E. 2001 Evolution and structure of sink-flow turbulent boundary layers. J. Fluid Mech. 428, 127.CrossRefGoogle Scholar
Katul, G. & Vidakovic, B. 1996 The partitioning of attached and detached eddy motion in the atmospheric surface layer using Lorentz wavelet filtering. Boundary-Layer Meteorol. 77 (2), 153172.CrossRefGoogle Scholar
Katul, G.G., Porporato, A. & Nikora, V. 2012 Existence of $k^{-1}$ power-law scaling in the equilibrium regions of wall-bounded turbulence explained by Heisenberg's eddy viscosity. Phys. Rev. E. 86 (6), 066311.CrossRefGoogle ScholarPubMed
Kunkel, G.J. & Marusic, I. 2006 Study of the near-wall-turbulent region of the high-Reynolds-number boundary layer using an atmospheric flow. J. Fluid Mech. 548, 375402.CrossRefGoogle Scholar
Lee, M. & Moser, R.D. 2015 Direct numerical simulation of turbulent channel flow up to ${R}e_\tau \approx 5200$. J. Fluid Mech. 774, 395415.CrossRefGoogle Scholar
Madhusudanan, A., Illingworth, S.J. & Marusic, I. 2019 Coherent large-scale structures from the linearized Navier–Stokes equations. J. Fluid Mech. 873, 89109.CrossRefGoogle Scholar
Marusic, I., Chauhan, K.A., Kulandaivelu, V. & Hutchins, N. 2015 Evolution of zero-pressure-gradient boundary layers from different tripping conditions. J. Fluid Mech. 783, 379411.CrossRefGoogle Scholar
Marusic, I., Mathis, R. & Hutchins, N. 2010 Predictive model for wall-bounded turbulent flow. Science 329 (5988), 193196.CrossRefGoogle ScholarPubMed
Marusic, I. & Monty, J.P. 2019 Attached eddy model of wall turbulence. Annu. Rev. Fluid Mech. 51, 4974.CrossRefGoogle Scholar
Marusic, I., Monty, J.P., Hultmark, M. & Smits, A.J. 2013 On the logarithmic region in wall turbulence. J. Fluid Mech. 716, R3.CrossRefGoogle Scholar
Mathis, R., Hutchins, N. & Marusic, I. 2009 Large-scale amplitude modulation of the small-scale structures in turbulent boundary layers. J. Fluid Mech. 628, 311337.CrossRefGoogle Scholar
Monty, J.P. & Chong, M.S. 2009 Turbulent channel flow: comparison of streamwise velocity data from experiments and direct numerical simulation. J. Fluid Mech. 633, 461474.CrossRefGoogle Scholar
Morrison, J.F. 2007 The interaction between inner and outer regions of turbulent wall-bounded flow. Phil. Trans. R. Soc. Lond. A 365 (1852), 683698.Google ScholarPubMed
Morrison, J.F., Subramanian, C.S. & Bradshaw, P. 1992 Bursts and the law of the wall in turbulent boundary layers. J. Fluid Mech. 241, 75108.CrossRefGoogle Scholar
Nickels, T.B., Marusic, I., Hafez, S. & Chong, M.S. 2005 Evidence of the ${k^{-1}_{1}}$ law in a high-Reynolds-number turbulent boundary layer. Phys. Rev. Lett. 95 (7), 074501.CrossRefGoogle Scholar
Nikora, V. 1999 Origin of the ‘$-$1’ spectral law in wall-bounded turbulence. Phys. Rev. Lett. 83 (4), 734.CrossRefGoogle Scholar
Orlandi, P., Bernardini, M. & Pirozzoli, S. 2015 Poiseuille and Couette flows in the transitional and fully turbulent regime. J. Fluid Mech. 770, 424441.CrossRefGoogle Scholar
Panton, R.L. 2007 Composite asymptotic expansions and scaling wall turbulence. Phil. Trans. R. Soc. Lond. A 365 (1852), 733754.Google ScholarPubMed
Perry, A.E. & Abell, C.J. 1977 Asymptotic similarity of turbulence structures in smooth-and rough-walled pipes. J. Fluid Mech. 79 (4), 785799.CrossRefGoogle Scholar
Perry, A.E. & Chong, M.S. 1982 On the mechanism of wall turbulence. J. Fluid Mech. 119, 173217.CrossRefGoogle Scholar
Perry, A.E., Henbest, S. & Chong, M.S. 1986 A theoretical and experimental study of wall turbulence. J. Fluid Mech. 165, 163199.CrossRefGoogle Scholar
Rosenberg, B.J., Hultmark, M., Vallikivi, M., Bailey, S.C.C. & Smits, A.J. 2013 Turbulence spectra in smooth-and rough-wall pipe flow at extreme Reynolds numbers. J. Fluid Mech. 731, 46.CrossRefGoogle Scholar
Saddoughi, S.G. & Veeravalli, S.V. 1994 Local isotropy in turbulent boundary layers at high Reynolds number. J. Fluid Mech. 268, 333372.CrossRefGoogle Scholar
Samie, M., Marusic, I., Hutchins, N., Fu, M.K., Fan, Y., Hultmark, M. & Smits, A.J. 2018 Fully resolved measurements of turbulent boundary layer flows up to ${R}e_{\tau } = 20\,000$. J. Fluid Mech. 851, 391415.CrossRefGoogle Scholar
Sillero, J.A., Jiménez, J. & Moser, R.D. 2014 Two-point statistics for turbulent boundary layers and channels at Reynolds numbers up to ${\delta }^{+}\approx 2000$. Phys. Fluids 26 (10), 105109.CrossRefGoogle Scholar
Tinney, C.E., Coiffet, F., Delville, J., Hall, A.M., Jordan, P. & Glauser, M.N. 2006 On spectral linear stochastic estimation. Exp. Fluids 41 (5), 763775.CrossRefGoogle Scholar
Townsend, A.A. 1961 Equilibrium layers and wall turbulence. J. Fluid Mech. 11 (1), 97120.CrossRefGoogle Scholar
Townsend, A.A. 1976 The Structure of Turbulent Shear Flow, 2nd edn. Cambridge University Press.Google Scholar
Wu, S., Christensen, K. & Pantano, C. 2019 Modelling smooth- and transitionally rough-wall turbulent channel flow by leveraging inner–outer interactions and principal component analysis. J. Fluid Mech. 863, 407453.CrossRefGoogle Scholar
Yoon, M., Hwang, J., Yang, J. & Sung, H.J. 2020 Wall-attached structures of streamwise velocity fluctuations in an adverse-pressure-gradient turbulent boundary layer. J. Fluid Mech. 885, A12.CrossRefGoogle Scholar
Figure 0

Figure 1. (a) Schematic of the experimental set-up in HRNBLWT showing relative positioning and movement of the four hot-wire probes ($HW_{1-4}$) for reconstructing the 2-D correlation corresponding to (i) $\varPhi$ and (ii) ${\varPhi }_{cross}$. Mean flow direction is along $x$. In the case of (ii), $HW_{3-4}$ are positioned at either $z_{r}\ll z_{o}$ or $z_{r} \gg z_{o}$, depending on the desired experiment (table 1). (b) Constant energy contours for ${\varPhi }$($z^{+}_{o} = z^{+}_{r}\approx 15) = 0.15$, computed from the present experimental and the converged DNS dataset of Sillero et al. (2014), plotted as a function of viscous-scaled wavelengths. Estimates from the DNS are box filtered along $y$ to mimic the spatial resolution of the hot-wire sensors. Figure concept for (a) has been adopted from Deshpande et al. (2020a).

Figure 1

Table 1. A summary of the ZPG TBL datasets comprising synchronized multi-point $u$-signals at $z^{+}_{r}$ and $z^{+}_{o}$ used to compute two types of 2-D $u$-spectra, ${\varPhi }$ and ${\varPhi }_{cross}$. The terminology has been described in § 2.1 and figure 1. Underlined values represent the approximate upper bound of the log region (0.15${Re_{\tau }}$; Marusic et al.2013), while the values in bold represent the near-wall reference location. Superscript ‘$+$’ denotes normalization in viscous units.

Figure 2

Figure 2. (a,c) Constant energy contours for ${\varPhi }$($z^{+}_{o}$), ${\varPhi }_{cross}$($z^{+}_{o}$, $z^{+}_{r}\approx 15$) and ${\varPhi }$($z^{+}_{r}\approx 15$) at an energy level of 0.15 plotted for (a) $z^{+}_{o}\approx 100$ and (c) $z^{+}_{o}\approx 0.15Re_{\tau }$. (b,d) Constant energy contours for ${\varPhi }_{ia}$($z^{+}_{o}$) and ${\varPhi }_{a}$($z^{+}_{o}$), computed via (3.1) and (3.2), plotted at the same energy level and $z^{+}_{o}$ as in (a,c), respectively. In (ad), contours on the left side correspond to those computed from the DNS data while those on the right are from the experimental data. Dashed green lines represent the linear relationship, ${\lambda }_{y}\sim {\lambda }_{x}$.

Figure 3

Figure 3. (a,b) Constant energy contours for ${\varPhi }_{a}$($z^{+}_{o}$) at an energy level of 0.15 plotted for various $z^{+}_{o}$ as a function of wavelengths scaled with (a) $z_{o}$ and (b) $\delta$. Contours in red and blue correspond to ${\varPhi }_{a}$ estimated for the experimental and DNS datasets respectively (table 1), with dark to light shading indicating an increase in $z^{+}_{o}$ following $100 \lesssim z^{+}_{o} \lesssim 0.15{Re_{\tau }}$ for $Re_{\tau }$ corresponding to respective datasets. Dashed green lines represent the linear relationship, ${\lambda }_{x} = 3{\lambda }_{y}$. Panels (c,d) show ${\varPhi }_{a}$($z^{+}_{o}$) integrated across ${\lambda }_{y}$ and ${\lambda }_{x}$ to obtain its corresponding 1-D version as a function of (c) ${\lambda }_{x}$ and (d) ${\lambda }_{y}$ respectively, each plotted with wavelengths scaled by $z_{o}$. Same colour coding is followed as that described for (a,b). (e,f) Pre-multiplied streamwise 1-D cospectra/spectra for the (e) Reynolds shear stress and (f) wall-normal velocity plotted as a function of ${\lambda }_{x}$ scaled with $z_{o}$. These data are from the $Re_{\tau } \approx 10\,000$ dataset of Baidya et al. (2017) for various $z^{+}_{o}$. Dark to light shading corresponds to the increase in $z^{+}_{o}$ following $100 \lesssim z^{+}_{o}\lesssim 0.15{Re_{\tau }}$, where $Re_{\tau } \approx 10\,000$.

Figure 4

Figure 4. Constant energy contours for (a,b) ${\varPhi }$($z^{+}_{o}$) and (c,d) ${\varPhi }_{ia}$($z^{+}_{o}$) at energy level of 0.15 plotted for various $z^{+}_{o}$ as a function of wavelengths scaled with (a,c) $z_{o}$ and (b,d) $\delta$, respectively. All data in (ad) correspond to the high $Re_{\tau }$ experimental dataset reported in table 1, with dark to light shading indicating an increase in $z^{+}_{o}$ following $100 \lesssim z^{+}_{o}\lesssim 0.15{Re_{\tau }}$. Dashed green lines represent the linear relationship, ${\lambda }_{y}\sim {\lambda }_{x}$.

Figure 5

Figure 5. Comparison of the normalized streamwise turbulence intensities obtained by integrating ${\varPhi }$ (${=}{\overline {u^2}}^{+}$), ${\varPhi }_{a}$ (${\approx }\overline {u^{2}}^{+}_\textit {active}$), ${\varPhi }_{ia}$ (${\approx }\overline {u^{2}}^{+}_\textit {inactive}$) and ${\varPhi }^{AE}_{ia}$ (${\approx }\overline {u^{2}}^{+}_\textit {inactive, AE}$) for the high $Re_{\tau }$ experimental dataset described in table 1. Also plotted for comparison is the well-resolved ${\overline {u^2}}^{+}$ measured by Samie et al. (2018) across a ZPG TBL maintained at an $Re_{\tau }$ comparable to the present experimental dataset. The dashed green line in (b) represents the logarithmic decay of ${\overline {u^2}}^{+}$ described by (1.1) with $A_{1}=0.98$ (Baars & Marusic 2020b), while the dash-dotted golden line in (a) represents a constant ${\overline {u^2}}^{+} = 2.7$.

Figure 6

Figure 6. (a) Constant energy contours for ${\varPhi }$($z^{+}_{o}$), ${\varPhi }_{cross}$($z^{+}_{o}$, $z^{+}_{r}\approx 0.15{Re_{\tau }}$) and ${\varPhi }$($z^{+}_{r}\approx 0.15Re_{\tau }$) at an energy level of 0.15 plotted for $z^{+}_{o}\approx 100$ and 318. (b) Constant energy contours for ${\varPhi }^{AE}_{ia}$($z^{+}_{o}$) and ${\varPhi }^{SS}_{ia}$($z^{+}_{o}$), computed via (5.1) and (5.2), plotted at the same energy level and $z^{+}_{o}$ as in (a). All contours in (a,b) are computed from the high $Re_{\tau }$ experimental data. Dashed green lines represent the linear relationship, ${\lambda }_{y}\sim {\lambda }_{x}$.

Figure 7

Figure 7. Values of ${\varPhi }$($z^{+}_{o}$) and ${\varPhi }^{AE}_{ia}$($z^{+}_{o}$) integrated across ${\lambda }_{y}$ and ${\lambda }_{x}$ to obtain their corresponding premultiplied 1-D version as a function of ${\lambda }_{x}$ (${\varPhi }_{x}$, ${\varPhi }^{AE}_{ia,x}$; solid line) and ${\lambda }_{y}$ (${\varPhi }_{y}$, ${\varPhi }^{AE}_{ia,y}$; dash-dotted line), respectively, for $z^{+}_{o}\approx$ (a) 100, (a) 200 and (c) 318. Also highlighted are the peaks/plateaus of ${\varPhi }^{AE}_{ia,x}$ and ${\varPhi }^{AE}_{ia,y}$ ($A_{1x}$, $A_{1y}$), along with those of ${\varPhi }_{x}$ and ${\varPhi }_{y}$ ($A'_{1x}$, $A'_{1y}$).

Figure 8

Figure 8. Contours for the linear transfer kernel (black), for $z^{+}_{r} \approx 15$, and the near-wall 2-D spectra (magenta) for the (a) $u$- and (b) $w$-velocity components. Here, the transfer kernels are computed at various $z^{+}_{o}$ from the DNS dataset of Sillero et al. (2014), described in table 1. Dark to light shading indicates an increase in $z^{+}_{o}$ following $100\lesssim z^{+}_{o}\lesssim 0.15Re_{\tau }$. The contour levels for the transfer kernels, ${| H_{L} |}^2$ and ${| G_{L} |}^2$ correspond to approximately 10 % of the maximum value recorded for the kernel at the respective $z^{+}_{o}$, while that for ${\varPsi }$($z^{+}_{r}\approx 15$) has intentionally been kept very low to highlight no overlap with the associated transfer kernel, ${| G_{L} |}^2$.