4.1 Partitioning of the flow into turbulent and non-turbulent sub-volumes

Vorticity is an appropriate and common discriminator between turbulent and non-turbulent regions of a generally turbulent flow (da Silva et al. Reference da Silva, Hunt and Eames2014). Hence, following Pope (Reference Pope2000), we define the intermittency factor as

(4.1) $$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D6FE}(z)\equiv \langle H(\unicode[STIX]{x1D714}-\unicode[STIX]{x1D714}_{0})\rangle , & & \displaystyle\end{eqnarray}$$

where $H$ is the Heaviside function, $\unicode[STIX]{x1D714}$ is the local vorticity magnitude and $\langle \cdot \rangle$ denotes a horizontal average. Defining the threshold $\unicode[STIX]{x1D714}_{0}$ for the turbulent/non-turbulent interface is to some degree arbitrary. In many free flows, external intermittency is characterized by very intense variations of the vorticity magnitude $\unicode[STIX]{x1D714}$ between the turbulent and non-turbulent sub-volumes and this feature yields $\unicode[STIX]{x1D6FE}(z)$ quite insensitive to the choice of $\unicode[STIX]{x1D714}_{0}$ , at least in a certain range (Kovasznay et al. Reference Kovasznay, Kibens and Blackwelder1970; Bisset, Hunt & Rogers Reference Bisset, Hunt and Rogers2002; Mellado, Wang & Peters Reference Mellado, Wang and Peters2009). In Ekman flow, however, two features makes the choice of a vorticity threshold delicate (figure 3 a): first, the statistical stationarity of the flow when compared to a growing boundary layer is different; in a growing boundary layer the turbulent part of the flow gradually engrosses non-turbulent fluid. Second, in Ekman flow there is an inviscid vortex-tilting mechanism (appendix A) constituting a vorticity source aloft the turbulent layer. As shown in appendix A, irrespective of $Re$ , this vortex tilting is a fundamental mechanism in Ekman flow that renders the outer, non-turbulent layer different from non-rotating external flows.

Figure 3. Intermittency factor versus height for case ri00 varying the intermittency threshold $\unicode[STIX]{x1D714}_{0}$ in the range $\widetilde{\unicode[STIX]{x1D714}}/32\leqslant \unicode[STIX]{x1D714}_{0}\leqslant 3\,\widetilde{\unicode[STIX]{x1D714}}$ with $\widetilde{\unicode[STIX]{x1D714}}$ as defined in (4.2).

We choose here $\unicode[STIX]{x1D714}_{0}=\widetilde{\unicode[STIX]{x1D714}}$ , where

(4.2) $$\begin{eqnarray}\displaystyle \widetilde{\unicode[STIX]{x1D714}}\equiv 7\unicode[STIX]{x1D714}_{rms}(\unicode[STIX]{x1D6FF}_{95}), & & \displaystyle\end{eqnarray}$$

as reference vorticity for the turbulent/non-turbulent distinction for three reasons. First, according to classical definitions of the boundary-layer height, such as $\unicode[STIX]{x1D6FF}_{95}$ , this level is at the verge of the part that is considered turbulent in a bulk sense. Second, we observe the scaling $\langle u_{i}u_{i}\rangle \propto z^{-4}$ for $0.75\lesssim z^{-}\lesssim 2$ (not shown), which is a signature of potential flow aloft a turbulent boundary layer (Phillips Reference Phillips1955). Third, the resulting profile $\unicode[STIX]{x1D6FE}(z)$ (figure 3) is similar to that found in non-rotating boundary layers (cf. Kovasznay et al. Reference Kovasznay, Kibens and Blackwelder1970).

While, as discussed above, this approach is well suited to distinguish the turbulent and non-turbulent regions in the outer layer of a neutrally stratified Ekman flow, the detection of global intermittency under stable stratification based on this method is difficult: contributions of the mean-velocity gradient dominate the turbulence contribution to the vorticity fluctuation close to the wall (Ansorge & Mellado Reference Ansorge and Mellado2014). To overcome the problem of partitioning the flow within the inner layer, we consider two horizontal high-pass filters of the velocity fields in Fourier space. For the first one, we define

(4.3) $$\begin{eqnarray}\displaystyle F_{\unicode[STIX]{x1D6FF}}(k_{h})\equiv \frac{1}{2}\left\{\text{erf}\left[\ln \left(\frac{k_{h}}{k_{\unicode[STIX]{x1D6FF}}}\right)\right]+1\right\},\quad \text{with}\;k_{h}\equiv \sqrt{k_{x}^{2}+k_{y}^{2}}, & & \displaystyle\end{eqnarray}$$

where $k_{x}$ and $k_{y}$ are wavenumbers in the streamwise and spanwise directions and the filter length scale is $k_{\unicode[STIX]{x1D6FF}}\equiv 2\unicode[STIX]{x03C0}/\unicode[STIX]{x1D6FF}$ . The filters $\mathscr{F}_{\unicode[STIX]{x1D6FF}}^{\pm }$ are then defined by the filter transfer functions $\pm (F_{\unicode[STIX]{x1D6FF}}-0.5)+0.5$ . That is, we consider the spectral decomposition of the flow fields into

(4.4a,b ) $$\begin{eqnarray}\displaystyle \boldsymbol{u}_{hi}\equiv \mathscr{F}_{\unicode[STIX]{x1D6FF}}^{+}\{\boldsymbol{u}\}\quad \text{and}\quad \boldsymbol{u}_{lo}\equiv \mathscr{F}_{\unicode[STIX]{x1D6FF}}^{-}\{\boldsymbol{u}\}=\boldsymbol{u}-\boldsymbol{u}_{hi}. & & \displaystyle\end{eqnarray}$$

As a second filter, we use the Reynolds decomposition where upper-case letters denote averages and lower-case letters fluctuations.

4.2 Filtering and intermittency factors

The first statistical property that we consider in this analysis is vorticity because of its pivotal role in defining turbulence intermittency (cf. da Silva et al. Reference da Silva, Hunt and Eames2014). In the neutrally stratified flow (case ri00), contributions from the high-pass filtered field  $\boldsymbol{u}_{hi}$ dominate the root mean square of the vorticity fluctuations  $\unicode[STIX]{x1D714}_{rms}$ at all heights (figure 4 a). The vorticity root mean square residing in the low-pass filtered field  $\boldsymbol{u}_{lo}$ is less than one-sixth of that contained in  $\boldsymbol{u}_{hi}$ . The same holds for the weakly stratified case ri15, supporting further the aforementioned and well-established similarity between the neutrally and weakly stratified flow regimes. When the stratification increases further, i.e. in case ri31, the vorticity root mean square in the high-pass filtered field begins to reduce while the contribution in the low-pass filtered field only increases slightly.

Figure 4. Vertical profiles of the vorticity root mean square (a) and TKE (b) of the unfiltered (thin solid), high-pass (thick, solid) and low-pass (thick dashed) filtered fields for case ri00 (black), ri15 (blue), ri31 (red) and ri62 (orange).

When stratification is increased to  $Ri_{B}=0.62$ (case ri62), $\boldsymbol{u}_{hi}$ contains much lower vorticity root mean square, in particular close to the wall ( $z^{-}<0.2$ ). There, the vorticity root mean square is largely explained by the low-pass filter contribution. Contributors to this vorticity root mean square are large-scale coherent motions. While the flow as a whole is undoubtedly turbulent, locally it does not quite seem turbulent in some regions (cf. figure 2 c,e). This situation is not any different from that in a turbulent jet as considered in the works of Townsend, Corrsin & Kistler (Corrsin Reference Corrsin1943; Townsend Reference Townsend1948, Reference Townsend1949; Corrsin & Kistler Reference Corrsin and Kistler1955). However, the standard indicator function of turbulence – based on the vorticity of the flow field  $\boldsymbol{u}$  (4.1) – does not work here. We are in the unfortunate situation where external intermittency occurs in the vicinity of the wall. Here, turbulent sub-volumes are not the only contributor to vorticity but also the non-turbulent sub-volumes possess substantial vorticity, which deems vorticity of the unfiltered field inappropriate to locally indicate small-scale activity.

Profiles of TKE (figure 4 b) also show the change from fluctuations dominated by small-scale activity in the neutrally and weakly stratified cases to fluctuations dominated by large-scale activity under strong stability. TKE, however, is more sensitive than the vorticity to the strong buoyancy oscillation in case ri62. In general, TKE is less sensitive than vorticity to the absence of small-scale turbulent motion close to the wall. Therefore, we measure intermittency factors based on the vorticity, and consider the filters introduced in this section.

Figure 5. Intermittency factor  $\unicode[STIX]{x1D6FE}$ with a threshold vorticity  $\unicode[STIX]{x1D714}_{0}=\widetilde{\unicode[STIX]{x1D714}}$ calculated from high-pass filtered field (thick solid: $\mathscr{F}_{\unicode[STIX]{x1D6FF}}^{+}$ ; thick dash–dotted: Reynolds’ decomposition) and unfiltered field (thin solid). Colours indicate the stratification as in figure 4. The secondary vertical axis applies to the neutrally stratified case only.

With respect to the flow-partitioning method based on unfiltered fields, most of the flow is turbulent, even in the strongly stable regime (figure 5). Owing to the strong shear in the surface layer, this classical method of measuring external intermittency fails to detect the localized absence of turbulence close to the wall evident in figure 2(c,e). Further, it yields a higher turbulent area fraction (up to  $z^{-}\approx 0.1$ in figure 5) as compared to the neutral reference. When a Reynolds decomposition is used, $\unicode[STIX]{x1D6FE}$ is reduced to approximately 0.5 in the buffer layer of the strongly stable regime, but remains very close to unity in immediate vicinity of the wall. A reduction of the turbulent area fraction by only 10 % in cases ri31 and ri62 does not represent an appropriate measure of global intermittency, reflecting the large-scale contribution to the vorticity root mean square in the inner layer (cf. figure 2). If high-pass filtered fields are used to partition the flow, the localized absence of turbulent motion in a vast part of the inner layer is correctly detected. The utility of a spectral decomposition is visualized in figure 2: the logarithm of normalized vorticity modulus reaches values of approximately 10 throughout the domain, even in regions where there is no mixing activity (panel c). The high-pass filter operation removes these contributions (panel d), and the vorticity modulus is significantly reduced in regions with less small-scale mixing. At the same time, for the neutrally stratified case, the consideration of filtered fields has no impact on  $\unicode[STIX]{x1D6FE}(z)$ above $z^{+}\simeq 20$ (figures 2 a and 2 b), and in figure 5 the three lines for the Reynolds-averaged high-pass filtered and unfiltered fields collapse, with only a 5 % deviation below the buffer region. Under stable stratification, a realistic reduction of the intermittency factor in the vicinity of the wall can – among the options considered here – only be achieved with the high-pass filter $\mathscr{F}_{\unicode[STIX]{x1D6FF}}^{+}$  (4.3).

Given the small variation of intermittency factors below $z^{+}\simeq 20$ , one might consider conditioning the whole boundary layer based on a two-dimensional partition map of the buffer layer. This was considered here as an alternative to a three-dimensional partitioning method. It turns out, however, that even within the inner layer the vertical coherence of the turbulent/non-turbulent partitioning is not perfect. While the following results qualitatively also hold for this easier approach to partitioning the flow, our analyses showed that turbulence elements may reach into the non-turbulent fraction, modifying in particular the statistics of the non-turbulent sub-volumes. This is a consequence of the complex geometry of the turbulent/non-turbulent interface as it may be inferred from figure 2. This contortion of the turbulent/non-turbulent interface renders the observed tendencies much less clear when this simplified two-dimensional partitioning method is employed. Another effect of a purely two-dimensional partitioning method based on the buffer layer is that effects of external intermittency in the statistics cannot be detected, since external intermittency mainly impacts on a flow above the buffer layer.

In summary, the above introduction of a high-pass filter operation provides a suitable generalization of the vorticity-based conditioning to flows where intermittency occurs in regions with intense shear. We expect this method to work for the broad class of problems where body forces suppress turbulent motion in a region of strong shear; particularly, this includes the global intermittency accompanying both the re-laminarization of a turbulent flow and the recovery of a laminar flow to a turbulent state. The capability to detect the absence of turbulent motion, also in the vicinity of the wall, allows for a decomposition of the flow into disjoint turbulent and non-turbulent sub-volumes. Hence, one may compute conditional statistics that do not mix up effects of a decreased intensity of turbulence on the one hand, and a partial re-laminarization of the flow on the other hand. This approach yields new insight into the dynamics of Ekman flow, including aspects of the logarithmic law under neutral stratification and the organization of patchy turbulence under very strong stratification, as laid out in § 5.

4.3 Wave-like motions

Besides the above decomposition in physical space, the high-pass filter operation establishes a spectral decomposition of the flow into large-scale wave-like motions and small-scale mixing eddies. This allows us to quantify the effects of waves on the statistics to a certain extent. In particular, under stable stratification, this aids the understanding of small-scale processes whose footprint in the statistics may otherwise be obscured by effects of waves or coherent large-scale motions.

Figure 6. (a) Residual of the flux $\langle bw\rangle$ in the term combining large-scale and small-scale motions as a fraction of the total flux. $\unicode[STIX]{x1D716}=10^{-3}B_{0}G$ is used as a regularization factor to avoid singularity when $\langle bw\rangle$ becomes very small. (b) Flux in the raw field $\langle bw\rangle$ , the high-pass filtered field $\langle (bw)_{hi}\rangle$ and in the low-pass filtered field $\langle (bw)_{lo}\rangle$ normalized by $\unicode[STIX]{x1D70E}_{bw}:=\sqrt{\langle bb\rangle \langle ww\rangle }$ . Colouring indicated in panel (a) is as in previous figures. The second vertical axis ( $z^{-}$ ) is valid for neutral stratification only.

A decomposition into turbulent and wavy modes is illustrated here by means of the buoyancy flux. Neglecting contributions from the mixed terms, it is

(4.5) $$\begin{eqnarray}\displaystyle \langle bw\rangle \simeq \langle b_{lo}w_{lo}\rangle +\langle b_{hi}w_{hi}\rangle & & \displaystyle\end{eqnarray}$$

within very small deviations (2 % within the boundary layer, 5 %–10 % around  $z=\unicode[STIX]{x1D6FF}$ where the flux is very small, figure 6 a). In the inner layer of the neutrally and weakly stratified cases, the buoyancy flux is entirely in the high-pass filtered contribution, i.e.  $\langle bw\rangle \simeq \langle b_{hi}w_{hi}\rangle$  (figure 6 b). There, the correlation between  $b$ and  $w$ is relatively large. Only in the non-turbulent region aloft the turbulent part of the boundary layer do contributions in the large-scale signal matter. Here, the correlation between  $b$ and  $w$ drops by one order of magnitude. Under strong stratification (case ri62), the turbulence is extinguished, and nearly all the flux resides in large-scale contributions. This flux is not governed by a turbulent process but rather by large-scale wave activity and may change sign (while the viscous flux locally increases as a consequence of the increased stratification that comes with a positive buoyancy flux), as shown in figure 6(b). Hence, this flux is characterized by a very small – sometimes even negative – correlation coefficient between  $b$ and  $w$ . In fact, the net transport $\int \langle bw\rangle \,\text{d}t$ is very close to zero (not shown) in the non-turbulent region aloft the turbulent part of the boundary layer. Such a small or no correlation between $b$ and $w$ is a feature of wave motions, whereas turbulent motion is characterized by non-zero correlation between $b$ and $w$ (Sutherland Reference Sutherland2010). This behaviour of the correlation coefficient between $b$ and $w$ suggests that the filter operation based on the length scale $\unicode[STIX]{x1D6FF}$ – as anticipated above – constitutes a decomposition of the flow into wave and turbulence modes.

5.1 External intermittency and the logarithmic law for Ekman flow

The logarithmic law is based on a similarity argument for the vertical gradient of streamwise velocity in the surface layer which is often expressed as

(5.1a ) $$\begin{eqnarray}\displaystyle \frac{\unicode[STIX]{x2202}U^{+}}{\unicode[STIX]{x2202}z^{+}}=\frac{1}{\unicode[STIX]{x1D705}z^{+}} & & \displaystyle\end{eqnarray}$$

(cf. von Kármán Reference von Kármán1930; Prandtl Reference Prandtl, Tollmien, Schlichting, Görtler and Riegels1961; Zanoun, Durst & Nagib Reference Zanoun, Durst and Nagib2003). Given a velocity profile, $\unicode[STIX]{x1D705}$ can be estimated as

(5.1b ) $$\begin{eqnarray}\displaystyle \hat{\unicode[STIX]{x1D705}}_{diff}=\frac{\unicode[STIX]{x2202}\ln z^{+}}{\unicode[STIX]{x2202}U^{+}}. & & \displaystyle\end{eqnarray}$$

Such an estimation of  $\unicode[STIX]{x1D705}$ poses challenges beyond the availability of data at only moderate Reynolds number (Spalart, Coleman & Johnstone Reference Spalart, Coleman and Johnstone2009). The main issue when estimating $\unicode[STIX]{x1D705}$ directly is a strong decline from $\unicode[STIX]{x1D705}(z^{+}\simeq 50)\simeq 0.42$ to $\unicode[STIX]{x1D705}\simeq 0.38$ at the upper end of the logarithmic layer. Spalart, Coleman & Johnstone (Reference Spalart, Coleman and Johnstone2008) proposed that a shifted origin for the logarithmic law yields a much better fit, but rejected this hypothesis later (Spalart et al. Reference Spalart, Coleman and Johnstone2009). A possible physical interpretation of this dip is the effect of the super-geostrophic wind maximum in Ekman flow located around  $z^{-}\approx 0.20$ (Ansorge & Mellado Reference Ansorge and Mellado2014), which corresponds to  $z^{+}\approx 300$ for the  $Re$ achieved here. Another possible reason is that in this range of heights, the flow is externally intermittent – a fundamental difference to channel flow for which the law was originally derived. Within non-turbulent sub-volumes of the flow, the application of a logarithmic law is not meaningful.

Figure 7. Deviation of the estimates for the von  Kármán constant based on its value at $z^{-}=100$ (cf. table 2). Estimates of $\hat{\unicode[STIX]{x1D705}}_{int}$ based on the integral formulation (5.2a ) are shown in black, estimates of $\hat{\unicode[STIX]{x1D705}}_{diff}$ based on the differential formulation in red. Thick, dashed lines are based on averages conditioned to turbulent patches ( $U|_{turb}$ ) and thin solid lines show conventional averages ( $U$ ).

In a laboratory context, with regard to atmospheric measurements, and when it comes to the parameterization of mean-velocity profiles, the integrated form of equation (5.1a ) is often more practical: integration of equation (5.1a ) over $z^{+}$ yields

(5.2a ) $$\begin{eqnarray}\displaystyle U^{+}=\frac{1}{\unicode[STIX]{x1D705}}\ln z^{+}+\mathscr{A}_{0}, & & \displaystyle\end{eqnarray}$$

and allows us to locally estimate $\unicode[STIX]{x1D705}$ as

(5.2b ) $$\begin{eqnarray}\displaystyle \hat{\unicode[STIX]{x1D705}}_{int} & = & \displaystyle \frac{\ln z^{+}}{U^{+}-\mathscr{A}_{0}}.\end{eqnarray}$$

As a consequence of the integration, equation (5.2b ) includes the additional unknown parameter $\mathscr{A}_{0}$ representing the lower boundary condition for the logarithmic layer. While $\mathscr{A}_{0}$ is a physically relevant and geometry-related parameter for the mean-velocity profile, it is unrelated to the fundamental problem of determining the von Kármán constant. We estimate here $\mathscr{A}_{0}$ together with $\unicode[STIX]{x1D705}$ from a least-square fit of the velocity profiles versus the ideal logarithmic profile (5.2a ). By construction, this approach also yields an estimate for the optimal value of $\unicode[STIX]{x1D705}$ which is consistent with the differential formulation (5.1a ).

The flow-conditioning method introduced in § 4.1 allows us to account for the effect of external intermittency on the logarithmic law by conditioning the mean velocity profile to the turbulent sub-volumes. While we use here $\unicode[STIX]{x1D714}_{0}=\widetilde{\unicode[STIX]{x1D714}}$  (4.2) as the threshold to discern turbulent and non-turbulent regions, in a qualitative way, the findings put forward here hold when $\unicode[STIX]{x1D714}_{0}$ is varied in the range $1/8<\unicode[STIX]{x1D714}_{0}/\widetilde{\unicode[STIX]{x1D714}}<1$ . When considering the conditioned profiles, both estimates for $\unicode[STIX]{x1D705}$ ((5.2b ) and (5.1b )) vary less with height in the region $50<z^{+}<200$ , as seen in figure 7. In particular, the problematic decline of the estimate for $\hat{\unicode[STIX]{x1D705}}_{diff}$ is reduced by approximately 50 % when only the turbulent fraction of the domain is considered. We propose hence the modified logarithmic law

(5.3) $$\begin{eqnarray}\displaystyle U_{turb}^{+}=\frac{1}{\unicode[STIX]{x1D705}}\ln z^{+}+\mathscr{A}_{0}. & & \displaystyle\end{eqnarray}$$

Using the velocity conditioned to the turbulent regions of the flow, this formulation takes into account effects of external intermittency in the logarithmic layer of the flow. The considerable improvement of the estimator for the von Kármán constant, $\unicode[STIX]{x1D705}_{diff}$ , provides strong evidence that the failure to establish a plateau in $\unicode[STIX]{x1D705}_{diff}(z^{+})$ is, at least partly, an effect of the entrainment of non-turbulent fluid into the logarithmic layer. As such, this effect is intrinsic to Ekman flow however high the Reynolds number and, contrary to possible other mechanisms with impact on the logarithmic law at intermediate Reynolds numbers, cannot be expected to cede when $Re$ is further increased. (In fact, the shifted-origin hypothesis for the logarithmic law put forward by Spalart et al. (Reference Spalart, Coleman and Johnstone2008) seems now again a lot more attractive than it appeared in the light of the findings in Spalart et al. (Reference Spalart, Coleman and Johnstone2009).)

Table 2. Estimates from conventional and conditioned velocity profiles for $A_{0}$ and $\unicode[STIX]{x1D705}$ based on a least-squares fit. The fitted region varies according to the column ‘interval’. The spread between the maximum and minimum value in the respective column is given for convenience.

While actually a consequence of external intermittency, this modification can be interpreted in analogy to a wake law, but it extends deep into the logarithmic layer. When rewritten in terms of the actual velocity profile, i.e. including the non-turbulent regions, our findings suggest the formulation

(5.4) $$\begin{eqnarray}\displaystyle U^{+}=\frac{1}{\unicode[STIX]{x1D705}}\ln z^{+}+\mathscr{A}_{0}+f_{ext.\,int.}(z^{-},z^{+}), & & \displaystyle\end{eqnarray}$$

where $f_{ext.\,int.}$ can be interpreted as a wake function representing the effect of external intermittency and is exactly prescribed by the difference $U^{+}-U|_{turb}^{+}$ of the average wind speed in the conditioned and unconditioned fields. Similarity properties and the exact dependency of the function $f_{ext.\,int.}$ on the non-dimensional heights $z^{-}$ and $z^{+}$ need to be identified.

With regards to absolute values of the parameters related to the logarithmic law, our conventional mean-velocity profiles support values for $\unicode[STIX]{x1D705}$ in the range $[0.389,0.413]$ – depending on the height range from which they are estimated (table 2). When the non-turbulent patches are excluded from the field, the estimate of $\unicode[STIX]{x1D705}$ increases as a consequence of the lower velocity $U^{+}|_{turb}<U^{+}$ appearing in the denominator of the estimators for $\unicode[STIX]{x1D705}$ . Along with an increasing effect of external intermittency, this impact increases with height: the impact on $\unicode[STIX]{x1D705}$ of using the conditioned profile instead of the conventional averages is a 2 % increase when estimated for $50<z^{+}<100$ , but already a $6\,\%$ increase when estimated for $120<z^{+}<240$ . When using the conditioned profile, dependency of both $\mathscr{A}_{0}$ and $\unicode[STIX]{x1D705}$ on the height range from which they are estimated decreases and the data only support the reduced range $0.41\lesssim \unicode[STIX]{x1D705}\lesssim 0.43$ for the von Kármán constant. We interpret this reduced uncertainty in $\unicode[STIX]{x1D705}$ as a consequence considering an additional relevant physical mechanism in the logarithmic layer of the flow.

Figure 8. Streamwise (a) and spanwise (b) auto-correlation function of the vertical component of velocity at three different heights in the buffer layer, surface layer and outer layer of the turbulent flow. Shown are the four cases ri00, ri15, ri31 and ri62 with colouring as in previous figures. Different line strokes indicate different heights above the surface as shown in the legend. The separations $\unicode[STIX]{x0394}x$ and $\unicode[STIX]{x0394}y$ are normalized with the boundary-layer depth for the respective stratified case at the time where the correlation is evaluated. Accounting for the symmetries of the horizontally doubly periodic problem, the auto-correlation functions are only shown through half the domain.

5.2 Global intermittency in the surface layer of stratified Ekman flow

One might ask: how does the structure of turbulence change under stable stratification? When considering the flow as a whole, the effect of stratification in the strongly stable case is tremendous (cf. Ansorge & Mellado Reference Ansorge and Mellado2014). A way to quantify the impact of stratification on turbulent motion is through streamwise and spanwise auto-correlation functions (figure 8). While a slight increase of stratification from $Ri=0$ to $Ri=0.15$ has only minor impact on the correlation, the strongly stratified cases ri31 and ri62, exhibit dramatically increased correlations at various heights throughout the boundary layer. The large-scale features, i.e. the global modes, also seen in the correlations under neutral stratification at a similar length scale (around $\unicode[STIX]{x0394}x^{-}\approx 2.5$ and $\unicode[STIX]{x0394}x^{-}\approx 5$ ) become more prominent, illustrating the important role which such coherent structures play in stratified Ekman flow. This persistence or even increasing dominance of large-scale modes under stable stratification in the near-wall region is also seen in a spectral analysis (not shown): the agreement of the length scale of these large-scale modes in Ekman flow ( ${\approx}5\unicode[STIX]{x1D6FF}$ as inferred from the correlation plots in figure 8) with that of the global modes under neutral stratification points to a link between them. While the presence of such large-scale modes and their emergence or persistence in stratified conditions (perhaps related to inertia–gravity waves) is a well-known feature in the core region of channel flow (García-Villalba & del Álamo Reference García-Villalba and del Álamo2011) and the outer region of Ekman flow (Shah & Bou-Zeid Reference Shah and Bou-Zeid2014a ), such modes of motion were not described near the wall so far (in fact, García-Villalba & del Álamo describe wall turbulence without global modes). We propose – in analogy to the presence of external intermittency in the surface layer under neutral stratification (cf. § 5.1) – that this is due to the large-scale global intermittency in the flow that transfers information about large-scale modes from the outer layer of the flow to the wall. As a consequence, even when the actual turbulent eddies are limited to a rather narrow spectral band due to stratification, large-scale modes from the outer layer penetrate deeply into the surface layer by governing the large-scale patterns of local laminarization.

But stratification not only impacts on correlations for large spatial separation: also for small spatial separation the correlation increases substantially when stratification becomes strong. This substantial increase is governed primarily by the large extent of the non-turbulent regions and is thus not a useful measure when it comes to the description of the small-scale turbulent motions within turbulent patches. Given the apparently very similar morphology of the turbulent regions as inferred from flow visualization, the difference in spectral or correlation analysis illustrates that these methods might not be the most suitable to investigate stratification-induced changes in the turbulent region of the flow. For the remainder of this work, we hence turn to a conditional analysis of one-point statistics.

While, as pointed out above, a correlation analysis might make one expect fundamental differences in the local structure of turbulent eddies, we show here that this is actually not the case. Therefore, the investigation is constrained to local properties of turbulent eddies within the patches of the flow that are turbulent with respect to the conditioning method introduced above in § 4.1. When this is done, the morphology of turbulence inside turbulent patches does not change substantially under stable stratification; it is rather the size of the turbulent flow fraction which causes order-one changes in conventional statistics.

Figure 9. Vertical profiles of  $U$ , $W$ , $B$ (a–c), and  $U_{hi}$ , $W_{hi}$ , $B_{hi}$ (d–f) conditioned to non-turbulent and turbulent sub-volumes of the flow. The lines are drawn if the area fraction contributing to a partition at a given level exceeds 1 %. The secondary vertical axis applies to the neutrally stratified case only.

Turbulent and non-turbulent sub-volumes of flow can be attributed to their source region by analysing the conditional statistics of buoyancy and velocity. Inside turbulent sub-volumes, the vertical velocity is positive and the streamwise velocity reduces with respect to the non-turbulent sub-volumes (figure 9 a,b,d,e). Reduced streamwise velocity inside a turbulent patch implies decreased shear in the turbulent partition. In terms of a quadrant analysis, this shows that turbulent sub-volumes mainly contribute to stress in the second quadrant ( $u^{\prime }<0$ , $w^{\prime }>0$ , ejections) while the non-turbulent sub-volumes contribute to stress in the fourth quadrant ( $u^{\prime }>0$ , $w^{\prime }<0$ , sweeps). Buoyancy behaves very similar to the streamwise velocity and reduces in turbulent sub-volumes with respect to their non-turbulent counterparts (figure 9 c,f). This series of differences between the statistical properties conditioned to turbulent and non-turbulent sub-volumes is a manifestation of the character of turbulence events as it is suggested by a structural approach to wall-bounded turbulence (cf. Adrian Reference Adrian2007): Turbulence is sustained by ejections from below, and the fluid inside these sub-volumes originates from the wall. The fluid in non-turbulent sub-volumes originates from the free stream.

The velocity and scalar profiles of the high-pass-filtered field $\boldsymbol{u}_{hi}$ conditioned to turbulent patches do not change substantially when the stratification is increased from neutral to the weakly and intermediately stratified cases (figure 9 d–f). In contrast, we observe significant changes for the strongly stratified case ri62. In this case, the turbulent area fraction is very small ( ${\approx}5\,\%$ ) and the turbulence is just about to burst, so that there exist no real turbulent patches yet (figure 2 e,f).

Figure 10. Viscous dissipation rate of TKE (a) and TKE (b) conditioned to turbulent and non-turbulent regions of the flow. The secondary vertical axis applies to the neutrally stratified case only.

An indicator of turbulence is the dissipation rate of TKE (figure 10 a). While in case ri62 the dissipation rate in the entire flow is decreased by approximately an order of magnitude, we see that when solely the turbulent sub-volumes are considered, the dissipation is reduced by only  ${\approx}5\,\%$ with respect to the neutrally stratified flow. The same holds for the cases ri31 and ri15 where the normalized dissipation conditioned to turbulent sub-volumes is insensitive to the imposed stratification. This further supports the above-mentioned similarity of the properties of the actual turbulence structures across the different regimes of stratification investigated here.

Another straightforward measure of turbulence is the TKE, which – in contrast to vorticity – is accessible through point measurements given sufficient stationarity of the flow. When considering the TKE, the concentration of dissipative flow structures into the turbulent patches of the flow is best observed in terms of its vertical component $\langle ww\rangle$ (figure 10 b). The uniformity of the small-scale structure of the turbulent flow regardless of stratification seen above is, however, obscured by other effects. The reason for this less clear distinction between the turbulent and non-turbulent sub-volumes are the large-scale structures seen in figure 2. These large-scale structures are more prominent in terms of absolute velocity than they are in terms of velocity derivatives, i.e. the vorticity (cf. §§ 3, 4.2).