3.1.1. Time-averaged velocity deficit

The time-averaged velocity deficit profiles ( $\Delta U\!/\!U_{\infty }$ , where $\Delta U = U_{\infty }(x) - \overline {U}(x,y)$ ) at five streamwise locations are presented in figure 3 for FST cases S1, S4, M5, L6 and L8. At the nearest location ( $x\!/\!D=1$ ), the profiles are nearly identical across all FST cases within each $C_T$ group, as expected from momentum theory ( $C_T \sim \int \overline {U} \Delta U r\textrm {d}r$ ). As the wakes develop, the velocity deficit profiles gradually evolve towards a Gaussian-like distribution – consistent with the far-wake shape typically assumed in engineering wake models (e.g. Bastankhah & Porté-Agel Reference Bastankhah and Porté-Agel2014) – with higher ${\textit{TI}}_{\infty }$ accelerating this transition. Although slight deviations from an ideal Gaussian shape remain near the wake edge, within the shear layer where tip vortices may persist, the profiles for $x\!/\!D \geqslant 3$ closely follow a Gaussian-like distribution for all $\{C_T,\textrm {FST}\}$ combinations.

Figure 3. Time-averaged velocity deficit profiles.

Considering FST effects, clear differences in both the magnitude and width of the velocity deficit profiles are observed for all $C_T$ after only a few diameters, highlighting the strong and immediate impact of FST. While a detailed analysis of wake velocity recovery is provided in § 3.3, it is already evident that both FST intensity and ILS affect the recovery of the maximum velocity deficit, $(\Delta U\!/\!U_{\infty })_{\textit{max}}$ , with differences between FST cases becoming more pronounced as $C_T$ increases. Relative to the closest approximation of a non-turbulent inflow (case S1), the presence of FST generally accelerates the reduction of $(\Delta U\!/\!U_{\infty })_{\textit{max}}$ . However, $(\Delta U\!/\!U_{\infty })_{\textit{max}}$ does not decrease monotonically with increasing FST intensity because of the concurrent effect of the ILS. For instance, $(\Delta U\!/\!U_{\infty })_{{max,L6}} \geqslant (\Delta U\!/\!U_{\infty })_{{max,M5}}$ across the entire measurement domain for $C_T \in \{0.7,0.9\}$ and up to $\sim 10D$ for $C_T = 0.5$ , clearly showing that, for similar FST intensities, a larger turbulence ILS leads to a slower recovery of the maximum velocity deficit.

In the far field ( $x\!/\!D\gtrsim 15$ ), the presence of a strong turbulent background appears to interfere with the wake’s Gaussian structure – particularly for $C_T\approx 0.5$ (e.g. see the L8 profiles at $x\!/\!D \geqslant 15$ ). The relatively weak momentum deficit remaining in this region, compared with the strength of the background turbulence, may be insufficient to ‘sustain’ a Gaussian distribution, with strong turbulent events potentially disrupting a self-similar evolution of the wake (Rind & Castro Reference Rind and Castro2012). At the farthest measurement station ( $x\!/\!D=20$ ), a residual velocity deficit profile is still measurable for all $\{C_T, \textrm {FST}\}$ combinations, emphasising the considerable distance needed for the mean velocity to fully recover.

In the lowest ${\textit{TI}}_{\infty }$ case (S1), the near-field differences in the width and magnitude of the $\Delta U\!/\!U_{\infty }$ profiles, driven by variations in $C_T$ , persist across the entire measurement range and remain clearly discernible even at $x\!/\!D=20$ . As ${\textit{TI}}_{\infty }$ increases, however, these $C_T$ -induced differences progressively diminish; by $x\!/\!D=20$ , the variations in $\Delta U\!/\!U_{\infty }$ between $C_T$ cases are barely noticeable in high- ${\textit{TI}}_{\infty }$ conditions. Thus, the presence of a strong turbulent background rapidly suppresses the influence of $C_T$ on $\Delta U\!/\!U_{\infty }$ , whereas in low FST intensity the wake retains a clear imprint of the operating point and a memory of its initial conditions far downstream.

Figure 4. Turbulence intensity profiles.

3.1.2. Turbulence intensity and kinetic energy

The profiles of turbulence intensity ( $TI = \sqrt {\overline {u^{\prime 2}}}/\overline {U}$ ), and turbine-added streamwise TKE ( $\Delta k = (k-k_{\infty })/U_{\infty }^2$ ) are shown in figures 4 and 5. To account for the slight streamwise decay of the background TKE, inherent to grid-generated turbulence, $k_{\infty }$ is computed at each $x$ -location as the average of the TKE measured by the two hot-wires farthest from the centreline, i.e. $k_{\infty }(x)=\langle k(x,y\!/\!D=1.8,2)\rangle$ , with $k = 0.5 \overline {u^{\prime 2}}$ .

At the nearest location ( $x\!/\!D=1$ ), both ${\textit{TI}}$ and $\Delta k$ in the wake increase with $C_T$ and ${\textit{TI}}_{\infty }$ – in contrast to the LES results of Li et al. (Reference Li, Zhang, Li and Yang2024) who reported a decrease in $\Delta k$ with increasing ${\textit{TI}}_{\infty }$ – while the influence of the inflow ILS appears secondary. For all { $C_T$ , FST} combinations, a peak of turbine-induced TKE is observed in the rotor tip shear layer, whose magnitude increases with both $C_T$ and ${\textit{TI}}_{\infty }$ . As the wake develops, the tip shear layer expands inward and outward, resulting in a decrease in the TKE peak and an initial rise in the centreline TKE, which then gradually decays as the wake mixes with the ambient flow. A similar build-up of the centreline ${\textit{TI}}$ , fuelled notably by the high-shear tip region, is also observed in the near field before the turbulence intensity begins to decay downstream. While the turbine-added TKE profiles for low- and medium- ${\textit{TI}}_{\infty }$ cases exhibit the characteristic saddle shape of self-similar axisymmetric wakes throughout the measurement domain, the presence of a strong turbulent background disrupts this structure (see case L8), mirroring the breakdown of self-similar Gaussian velocity deficit profiles. Interestingly, Rind & Castro (Reference Rind and Castro2012) reported a similar behaviour in the far field of a solid disc ( $x\!/\!D \geqslant 65$ ), showing that the presence of a sufficiently strong turbulent background ( ${\textit{TI}}_{\infty } \geqslant 3.3\,\%$ in their experiments) suppresses the possibility of self-similarity in the far wake due to the substantial transformation of the wake’s turbulence structure by the FST, whereas self-similar behaviour was observed for ${\textit{TI}}_{\infty } \leqslant 1.2\,\%$ . This loss of self-similarity was particularly evident in the turbulence normal stresses, which deviated from their typical self-similar cross-stream behaviour (the saddle shape), gradually flattening across the radial axis and aligning with free-stream levels, as observed in our wind turbine wake experiments.

Figure 5. Turbine-added TKE profiles. Note the change in the abscissa scale across the different $C_T$ cases.

The rate at which ${\textit{TI}}$ and $\Delta k$ decay in the near field increases as both $C_T$ and ${\textit{TI}}_{\infty }$ increase, consistent with findings on porous-disc wakes (Bourhis & Buxton Reference Bourhis and Buxton2024; Li et al. Reference Li, Zhang, Li and Yang2024). Near the turbine ( $x\!/\!D \leqslant 3$ ), the following trend is observed: $\Delta k_{{{\textit{Group}} 3 (L8)}}\geqslant \Delta k_{{{\textit{Group}} 2 (S4,M5,L6) }}\geqslant \Delta k_{{{\textit{Group}} 1 (S1)}}$ . However, this relationship reverses farther downstream ( $x\!/\!D \gtrsim 15$ ), where $\Delta k_{{L8}} \leqslant \Delta k_{{L6,M5,S4}}\leqslant \Delta k_{{S1}}$ , indicating a faster mixing of the low-TKE background flow with the high-TKE wake as ${\textit{TI}}_{\infty }$ increases. The faster decay of ${\textit{TI}}$ and TKE in the near field as ${\textit{TI}}_{\infty }$ increases likely results from enhanced turbulence mixing due to both higher ${\textit{TI}}_{\infty }$ and an increased initial $\Delta k$ . For group 2 cases (S4, M5 and L6), larger variations in $\Delta k$ are observed in the near field ( $x\!/\!D \lesssim 5$ ) than in the far field ( $x\!/\!D \gtrsim 15$ ), which may be attributed to differences in ILS. For instance, when comparing cases L6 and M5 at $x\!/\!D=3$ , $\Delta k_{y=0,{L6}} \lt \Delta k_{y=0,{M5}}$ for all $C_T$ , in contrast to the general trend of increasing $\Delta k$ with higher ${\textit{TI}}_{\infty }$ , suggesting that a larger ILS may slow the dissipation of the turbine-added TKE.

At $x\!/\!D = 3$ , the turbulence intensity exhibits distinct behaviour depending on $C_T$ : for $C_T\in \{0.5,0.7\}$ , ${\textit{TI}}_{{L8}} \geqslant {\textit{TI}}_{{M5}}\geqslant {\textit{TI}}_{{S4}} \geqslant {\textit{TI}}_{{S1}}$ , consistent with the increase in ${\textit{TI}}_{\infty }$ (figure 4). For $C_T = 0.9$ , however, the trend is reversed, with ${\textit{TI}}_{{L8}} \leqslant {\textit{TI}}_{{M5,S4}} \leqslant {\textit{TI}}_{{S1}}$ . This inversion is likely a consequence of the substantially higher wake ${\textit{TI}}$ levels at large $C_T$ , which amplify the difference between the wake and background turbulence intensities, thereby enhancing wake mixing and accelerating the dissipation of ${\textit{TI}}$ in the near field. This rapid decay of ${\textit{TI}}$ in the near field is further intensified in high- ${\textit{TI}}_{\infty }$ inflows. In the far field, wake ${\textit{TI}}$ levels gradually converge towards background levels, such that the cases with the highest ${\textit{TI}}_{\infty }$ also exhibit the largest ${\textit{TI}}$ within the wake. By definition, the decay rate of ${\textit{TI}}$ depends on both the mean velocity recovery and the dissipation of the TKE – processes that evolve at different rates – which explains why $\Delta k$ and ${\textit{TI}}$ do not exhibit identical streamwise evolution.

Figure 6. Streamwise turbulence ILS profiles.

Interestingly, in the highest ${\textit{TI}}_{\infty }$ case (L8), the wake turbulence intensity becomes nearly equal to the free-stream level ( $TI \approx {\textit{TI}}_{\infty }$ ) beyond $x\!/\!D \gtrsim 15$ , resulting in quasi-flat ${\textit{TI}}$ profiles in the far field for all $C_T$ (figure 4). Similarly, the turbine-added TKE decays to $\Delta k \approx 0$ (figure 5), consistent with the findings of Rind & Castro (Reference Rind and Castro2012). Thus, although a mean momentum deficit persists in the far field – evidenced by the small time-averaged velocity deficit at $x\!/\!D=20$ – the far wake no longer exhibits elevated turbulence levels. The faster decay of $\Delta k$ relative to $\Delta U$ indicates that the background TKE is entrained and mixed into the wake more efficiently than the momentum. This observation is consistent with the cylinder wake results of Buxton & Chen (Reference Buxton and Chen2023), who found that the TKE is entrained more efficiently than both mass and momentum in the near field in the presence of FST. Consequently, it results in a scenario where the wind turbine far wake becomes a flow region distinct from the free stream solely by a reduced mean momentum, rather than by elevated turbulence levels. Zhang, Yang & He (Reference Zhang, Yang and He2023) reported a comparable behaviour in their LES of wind turbine wakes under various ABL inflow conditions, identifying a far-field region ( $x\!/\!D \gtrsim 40$ ) where the turbine-added TKE had fully homogenised with that of the free stream despite a persisting momentum deficit. They further observed that the full dissipation of $\Delta k$ occurred closer to the turbine as ${\textit{TI}}_{\infty }$ increased, aligning with our observations.

3.1.3. Turbulence integral length scale

Figure 6 shows the profiles of streamwise turbulence ILS, ${\mathcal L}_{x}$ , for FST cases S1, S4, M5, L6 and L8. The turbulence ILS in the wake is computed in a similar manner to the background turbulence ILS, as ${\mathcal L}_{x} = \overline {U}\int ^{\tau _0}_0 R'(\tau ){\rm d}\tau$ , with $R'(\tau _0) = 0.1$ . Although the application of Taylor’s frozen turbulence hypothesis in the near wake may introduce some additional uncertainty in estimating ${\mathcal L}_x$ , the consistent evolution of the profiles from the near to far field across all wakes suggests that any error introduced by this assumption remains small.

Similar to the velocity deficit, an ILS ‘deficit’ is observed in the near field for all { $C_T$ , FST} combinations, with ${\mathcal L}_{x}(x\!/\!D=1)$ consistently smaller than the background ILS. The rotor acts as a high-pass filter, suppressing the largest scales of the incoming turbulence (Chamorro et al. Reference Chamorro, Guala, Arndt and Sotiropoulos2012b ). This effect is particularly pronounced for the M# and L# cases, whose ILS radial profiles exhibit steep gradients near the wake edge, whereas in the S# cases the profiles are nearly flat – although ${\mathcal L}_{x}(x\!/\!D=1)$ remains slightly smaller than the background ILS. As both $C_T$ and $\varLambda$ increase, the streamtube within which large structures are filtered broadens radially, a trend further reflected in the wider ILS profiles observed at high $C_T$ .

Interestingly, further downstream, the evolution of ${\mathcal L}_{x}$ in the wakes depends strongly on the inflow ILS. For cases S#, the ILS in the wakes exceeds that of the inflows for $x\!/\!D \gtrsim 3$ . In particular, the peak in ${\mathcal L}_x$ around $y\!/\!D \approx 0.6$ grows and shifts outward as the wake spreads, highlighting the progressive development of coherent structures in the tip shear layer. These structures grow with increasing $x$ and $C_T$ , with ${\mathcal L}_{x,{\textit{Low-}}C_T}\leqslant {\mathcal L}_{x,{\textit{Med-}}C_T}\leqslant {\mathcal L}_{x,{\textit{High-}} C_T}$ throughout the measurement domain. A similar behaviour has been reported for porous-body wakes developing in a non-turbulent background: small vortices, initially confined to the tip shear layer, merge and form larger structures as the shear layer develops (Bourhis & Buxton Reference Bourhis and Buxton2024; Cicolin et al. Reference Cicolin, Chellini, Usherwood, Ganapathisubramani and Castro2024). It can be noted that shear-layer instability, analogous to vortex shedding in bluff-body wakes, is one of two mechanisms proposed for the onset of wake meandering (e.g. Yang & Sotiropoulos Reference Yang and Sotiropoulos2019). The other, which underpins the dynamic wake meandering (DWM) model (Larsen et al. Reference Larsen, Madsen, Thomsen and Larsen2008), hypothesises that wind turbine wakes are passively advected by large-scale free-stream eddies that drive their meandering motion. While this topic is discussed in more detail in § 3.5, it is worth noting here that, for small- ${\mathcal L}_x$ FST cases (S#), the largest wake structures originate in the tip shear layer, grow downstream and are influenced by the turbine thrust coefficient – and hence its porosity – sharing similarities with bluff-body shear-layer behaviour.

In contrast, for the M# and L# cases, the ILS within the wakes remains smaller than the background ILS, with no peak in ${\mathcal L}_x$ in the tip shear layer – the rotor’s high-pass filtering effect persists across the entire measurement domain. For these cases, ${\mathcal L}_x$ in the wake gradually aligns with that of the free stream, akin to the recovery of the velocity deficit, with a larger background ILS promoting a faster recovery of ${\mathcal L}_x$ . Unlike the S# cases, ${\mathcal L}_{x,{\textit{Low-}}C_T}\geqslant {\mathcal L}_{x, {\textit{Med-}}C_T}\geqslant {\mathcal L}_{x, {\textit{High-}} C_T}$ throughout the wake, indicating a faster recovery of ${\mathcal L}_x$ at lower $C_T$ . This behaviour can be qualitatively interpreted by analogy with porous discs: at higher porosity (lower $C_T$ ), larger turbulence structures pass through the rotor without being filtered, leading to slightly larger ${\mathcal L}_x$ in the near field and a faster recovery.

In summary, for cases S#, the large-scale wake structures are primarily turbine-induced, shear-layer-generated coherent structures whose evolution is strongly influenced by the turbine operating point. Structures originating in the tip shear layer grow and propagate towards the background flow, leading to an ILS within the wake that exceeds the inflow ILS. In contrast, for M# and L# FST cases, the ILS within the wake recovers similarly to ${\textit{TI}}$ and $\Delta U$ , progressively increasing to adjust with that of the inflow turbulence, with larger background ILS promoting a faster adjustment of the ILS. Enhanced wake meandering, vortex–vortex interaction between the FST and the wake, or the entrainment of large eddies from the free stream could explain the progressive adjustment of the ILS. For the FST parameter space examined, distinct interactions between the background flow and the wake are observed depending on ${\mathcal L}_x$ : for ${\mathcal L}_x \lesssim 0.5D$ , the growth of structures in the wake appears to be primarily driven by turbine-induced structures, while for ${\mathcal L}_x \gtrsim 1D$ , the growth of wake structures is predominantly fuelled by the background flow. It should be noted, however, that this threshold may also depend on the spanwise ILS, ${\mathcal L}_y$ , as well as on $\varLambda$ , or $C_T$ , whose effects cannot be separated in the present study.

3.2.1. Wake width based on the time-averaged velocity deficit $\Delta U$

Figure 7 shows the streamwise evolution of the time-averaged wake width, $\delta (x)$ , for all 24 { $C_T$ , FST} combinations. At a given streamwise location $x$ , the time-averaged wake width is defined as the radial location at which the time-averaged velocity deficit is $10\,\%$ that of the maximum, i.e. $\delta (x)$ such that $\Delta U(x,\delta ) = 0.1\Delta U_{\textit{max}}(x)$ . Alternative thresholds and definitions of the wake width were tested and found not to change the evolution of $\delta (x)$ . As illustrated in figure 8, two mechanisms contribute to the growth of the time-averaged wake width $\delta (x)$ : (i) the physical growth of the instantaneous wake through the entrainment of background flow into the wake ( $\delta _i(x,t)$ increasing with $x$ ), and (ii) an apparent widening, in a time-averaged sense, resulting from the large-scale lateral displacement of the entire wake due to meandering. While we analyse this metric – widely used in engineering wind turbine wake models – without distinguishing the two contributions in that section, we will further discuss the influence of wake meandering on $\delta (x)$ in § 3.5.

Figure 7. Streamwise evolution of the time-averaged wake width $\delta (x)$ .

Figure 8. Sketch illustrating the contribution of wake meandering to the time-averaged wake width $\delta (x)$ . Here, $\delta _i(x,t)$ is the instantaneous wake width, determined from a single snapshot of the wake. Reproduced, with permission, from Kankanwadi & Buxton (Reference Kankanwadi and Buxton2023).

The most striking observation from figure 7 is the presence of a turning point in the slope of $\delta (x)$ – particularly in highly turbulent inflows – beyond which the wake grows noticeably more slowly than upstream. All wakes initially grow linearly with streamwise distance, consistent with the frequently reported behaviour of wind turbine near wakes. Most engineering wake models similarly assume a linear wake growth, $\delta = \lambda x + \beta$ , with a wake growth rate $\lambda$ that is independent of the streamwise position (e.g. Bastankhah & Porté-Agel Reference Bastankhah and Porté-Agel2014). However, our results show that this linear growth persists only up to a streamwise distance from the turbine that depends on $C_T$ and the background turbulence. Except for the fully open grid case (S1), where wakes grow nearly linearly over the entire measurement range, a change in the slope of $\delta (x)$ is observed for all FST cases, becoming sharper and occurring closer to the turbine as ${\textit{TI}}_{\infty }$ increases. Notably, in the highest- ${\textit{TI}}_{\infty }$ case (L8), the wake width exhibits a quasi-asymptotic evolution for $x\!/\!D \gtrsim 7$ , with $\delta (x)$ approaching a plateau, whereas in the medium- ${\textit{TI}}_{\infty }$ cases (group 2), the deceleration of the wake expansion is more progressive along the wake and begins farther downstream. Although observed for all $C_T$ , this change in the wake expansion rate is more pronounced at higher $C_T$ . Interestingly, the inflection point in $\delta (x)$ for L8 approximately coincides with the downstream location where both ${\textit{TI}}$ and the turbine-added TKE have nearly homogenised with that of the background flow. The absence of a significant TKE and ${\textit{TI}}$ gradient between the wake and the ambient flow may lead to less efficient mixing and turbulent diffusion, ultimately resulting in reduced wake expansion rates.

Focusing on the near field ( $x\!/\!D \lesssim 7$ ), we observe a clear increase in $\delta$ as both $C_T$ and ${\textit{TI}}_{\infty }$ increase. Specifically, case L8 yields the widest wake, S1 the narrowest and the evolution of $\delta$ follows the order $\delta _{ {{\textit{Group}} 3}} \geqslant \delta _{{{\textit{Group}} 2}} \geqslant \delta _{ {{\textit{Group}} 1}}$ . Similarly, we observe that $\delta _{\textit{High}-C_{T}} \geqslant \delta _{\textit{Med}-C_{T}}\geqslant \delta _{\textit{Low}-C_{T}}$ , a trend that holds true for all measurement stations and FST cases. Focusing on the group 2 FST cases, we observe that $\delta _{{S4,M5}} \geqslant \delta _{{L3,L6}}$ across the entire measurement range for $C_T = 0.5$ , and up to $x\!/\!D \approx 10$ for $C_T \in \{0.7, 0.9\}$ . Since ${\textit{TI}}_{\infty ,{L6}} \geqslant {\textit{TI}}_{\infty ,{M5}} \geqslant {\textit{TI}}_{\infty ,{S4}}$ , one might a priori expect that $\delta _{{S4,M5}} \leqslant \delta _{{L6}}$ . However, given the considerably larger inflow ILS in cases L3 and L6 ( ${\mathcal L}_x \sim 2D$ ) compared with S4 ( ${\mathcal L}_x \sim 0.5D$ ) and M5 ( ${\mathcal L}_x \sim 1D$ ), we may conclude that increasing the inflow ILS leads to a reduction in the time-averaged wake width in the near field. Interestingly, Kankanwadi & Buxton (Reference Kankanwadi and Buxton2023) reported a reduction in the instantaneous near-wake width ( $\overline {\delta _i}$ ) downstream of a cylinder for inflows with large ILS, as well as a reduction in the time-averaged wake width ( $\delta$ ) for $x\!/\!D \lesssim 3$ , in agreement with our results. Farther downstream ( $x\!/\!D \gtrsim 4$ ), however, they observed that wake meandering – enhanced by larger inflow ILS – compensated for the reduction in $\overline {\delta _i}$ , yielding a larger $\delta$ than in a non-turbulent inflow. In our experiments, wake meandering may not fully compensate for the decrease in $\overline {\delta _i}$ caused by larger inflow ILS – particularly at low $C_T$ , where the higher rotor porosity may lead to weaker wake meandering – which could explain the observed reduction in $\delta$ with increasing ILS within the group 2 cases. A more detailed analysis of large-scale wake motions will be presented in § 3.5.

In the far field, for group 3 FST cases, a quasi-plateau evolution of $\delta$ is observed for all $C_T$ . For group 2, a slowdown in the wake width growth is evident, whereas for group 1, the evolution remains nearly linear across the entire measurement range. Interestingly, for $C_T=0.9$ , the far-field wake width is larger in the lowest- ${\textit{TI}}_{\infty }$ case (S1) than in the highest- ${\textit{TI}}_{\infty }$ case (L8), which contrasts with the commonly reported trend that increasing ${\textit{TI}}_{\infty }$ leads to wider wind turbine wakes (though most studies have focused on the near field). This observation, however, aligns with recent findings on porous-disc wakes, where larger far wakes were observed for low-to-zero turbulence intensity inflows compared with high- ${\textit{TI}}_{\infty }$ ones (Vinnes et al. Reference Vinnes, Neunaber, Lykke and Hearst2023; Bourhis & Buxton Reference Bourhis and Buxton2024).

Figure 9. Wake growth rates calculated from $\lambda = \langle {\textrm {d}\delta /\textrm {d}x}\rangle$ for (a) $2 \leqslant x\!/\!D \leqslant 7$ , and (b) $15 \leqslant x\!/\!D \leqslant 20$ .

Figures 9(a) and 9(b) present the 24 wake growth rates $\lambda = \langle \textrm {d} \delta /\textrm {d}x \rangle$ , calculated for two distinct intervals: one in the near field, calculated from the mean gradient of $\delta (x)$ for $2 \leqslant x\!/\!D \leqslant 7$ , and one in the far field, calculated from the mean gradient of $\delta (x)$ for $15 \leqslant x\!/\!D \leqslant 20$ . In the near field, we observe that $\lambda$ increases with both $C_T$ and ${\textit{TI}}_{\infty }$ . In this wake region, the variations in $\lambda$ with $C_T$ are more pronounced at high ${\textit{TI}}_{\infty }$ than at low ${\textit{TI}}_{\infty }$ , with also larger differences between FST cases at higher $C_T$ . While ${\mathcal L}_x$ clearly affects the wake width $\delta$ , its effect on $\lambda$ appears secondary compared with ${\textit{TI}}_{\infty }$ and $C_T$ . However, in the far wake $x\!/\!D \gtrsim 15$ , we observe the opposite trend: a decrease in $\lambda$ as ${\textit{TI}}_{\infty }$ increases. Importantly, this change in how FST affects wind turbine wake spreading rates aligns with established entrainment behaviours for bluff and porous bodies. Kankanwadi & Buxton (Reference Kankanwadi and Buxton2020, Reference Kankanwadi and Buxton2023) reported that both FST intensity and ILS enhance the entrainment and wake growth rates in cylinder near wakes, while FST intensity suppresses entrainment in the far wake. Moreover, Chen & Buxton (Reference Chen and Buxton2023, Reference Chen and Buxton2024) identified a ‘cross-over location’ in cylinder wakes, located approximately $15D$ downstream (for the specific Reynolds number and FST ‘flavour’ parameter space studied), beyond which the wakes spread at a slower rate. Similarly, Vinnes et al. (Reference Vinnes, Neunaber, Lykke and Hearst2023), Bourhis & Buxton (Reference Bourhis and Buxton2024) reported wider porous-disc wakes in the near field when exposed to FST, however, both wake growth and entrainment rates in the far field were found to decrease as FST intensity increased. The similar variation in wind turbine wake growth rates exposed to FST, along with the presence of a similar turning point in the wake width streamwise evolution further highlights the similarities between the entrainment behaviours observed in wind turbine and bluff-body wakes.

3.2.2. Modelling of the near-field wake growth rate $\lambda _{[2D-7D]}$

Meaningful insights can be drawn by comparing the near-field wake growth rate dataset, $\lambda _{[2D-7D]}$ (figure 9 a), with standard wake growth rate models. Early studies based on the top-hat Jensen velocity model assumed a constant growth rate: Jensen (Reference Jensen1983) originally proposed $\lambda =0.1$ , while later work recommended $\lambda =0.075$ for onshore and $\lambda =0.03 - 0.05$ for offshore wind turbines (Mortensen et al. Reference Mortensen, Heathfield, Myllerup, Landberg and Rathmann2007; Barthelmie & Jensen Reference Barthelmie and Jensen2010). Although these values broadly agree with our measurements, the assumption of a constant growth rate is clearly inadequate. In recent decades, more sophisticated wake growth rate models have emerged, typically obtained by fitting linear or power laws to $\lambda$ datasets from LES, laboratory-scale experiments, or full-scale measurements. Several studies report a linear relationship between the wake growth rate and ${\textit{TI}}_{\infty }$ , as $\lambda = a {\textit{TI}}_{\infty } + b$ , with varying $\{a,b\}$ coefficients: Niayifar & Porté-Agel (Reference Niayifar and Porté-Agel2016) found $a = 0.38$ and $b=0.004$ (LES); Carbajo Fuertes, Markfort & Porté-Agel (Reference Carbajo Fuertes, Markfort and Porté-Agel2018) obtained $a = 0.35$ and $b=0$ (field measurements); and Cheng et al. (Reference Cheng, Zhang, Zhang and Xu2019) reported $a = 0.223$ and $b=0.022$ (LES). These empirical relationships were obtained with turbines operating at a single $C_T$ ( $C_T \approx 0.8$ ) and do not consider the influence of the FST length scale. Fitting $\lambda = a {\textit{TI}}_{\infty } + b$ to the entire $\lambda _{[2D-7D]}$ dataset yields a poor fit ( $R^2=0.621$ , with $a=0.592$ and $b=0.022$ ), mainly due to the strong dependence of $\lambda _{[2D-7D]}$ on $C_T$ . When $C_T$ cases are treated separately, the fits improve substantially, supporting a linear relationship between ${\textit{TI}}_{\infty }$ and $\lambda _{[2D-7D]}$ . For example, for $C_T \approx 0.5$ , $a=0.47$ , $b=0.013$ ( $R^2 = 0.907$ ); for $C_T \approx 0.7$ , $a=0.62$ , $b=0.019$ ( $R^2 = 0.929$ ); and for $C_T \approx 0.9$ , $a=0.68$ , $b=0.033$ ( $R^2 = 0.850$ ). Building on these observations, we fitted the combined model to the full dataset: $\lambda _{[2D-7D]} = a C_T{\textit{TI}}_{\infty } + b C_T + c{\mathcal L}_x$ , obtaining $a = 0.83$ , $b = 0.032$ , $c \sim 10^{-11}$ , and a significantly improved $R^2 = 0.914$ (grey lines in figure 9 a). This empirical model provides a reasonable approximation of the wake growth rate in the near field, while further highlighting the negligible influence of ${\mathcal L}_x$ compared with ${\textit{TI}}_{\infty }$ and $C_T$ .

Recently, Ishihara & Qian (Reference Ishihara and Qian2018) proposed the following empirical power-law wake growth rate model based on LES data, $\lambda = 0.11 C_T^{1.07} {\textit{TI}}_{\infty }^{0.2}$ , which yields a poor fit with the current dataset ( $R^2 = 0.343$ ). Taking inspiration from this model, we fitted a similar power law: $\lambda _{[2D-7D]} = aC_T^{\alpha _1}{\textit{TI}}_{\infty }^{\alpha _2}{\mathcal L}^{\alpha _3}$ , resulting in $\lambda _{[2D-7D]} = 0.372C_T^{0.99}{\textit{TI}}_{\infty }^{0.53}$ ( $\alpha _3 \sim 10^{-11}$ ) with $R^2 = 0.923$ . While the $C_T$ exponent closely matches that of Ishihara & Qian (Reference Ishihara and Qian2018), our model shows a stronger dependence on ${\textit{TI}}_{\infty }$ . Our dataset includes eight FST intensity levels, compared with two in their study, which may explain the reduced sensitivity observed in their model.

Finally, both the linear and power-law fit models provide fairly good approximations of $\lambda _{[2D-7D]}$ across a wide range of $C_T$ and FST condition. While small $R^2$ differences prevent favouring one over the other, they clearly outperform most existing models, which are usually calibrated for a single $C_T$ and based on much smaller datasets.

3.2.3. Wake width based on the turbine-added TKE $\Delta k$

Analogous to the velocity deficit-based wake width $\delta$ , we define a characteristic wake width $\delta _{k}$ based on the turbine-added TKE $\Delta k$ . At a given streamwise location $x$ , $\delta _{k}$ is defined as the radial location where $\Delta k(x,\delta _{k})=0.1\Delta k_{\textit{max}}(x)$ . For the two highest ${\textit{TI}}_{\infty }$ cases (L7 and L8), the $\Delta k$ profiles become nearly flat in the far field; therefore, to ensure meaningful wake identification, we define a TKE-based wake only when $\Delta k_{\textit{max}}/U_{\infty }^2 \gt 0.001$ . The expansion rates of the TKE-based wakes, $\lambda _k = \langle \textrm {d}\delta _k / \textrm {d}x \rangle$ , are computed in the near and far fields from the mean gradient of $\delta _{k}$ for $2 \leqslant x\!/\!D \leqslant 7$ ( $\lambda _{k[2D-7D]}$ ), and $15 \leqslant x\!/\!D \leqslant 20$ ( $\lambda _{k[15D-20D]}$ ), respectively. Figures 10 and 11 show the streamwise evolution of $\delta _{k}(x)$ and the TKE-based expansion rates, $\lambda _k$ , for all 24 { $C_T$ , FST} combinations.

Figure 10. Streamwise evolution of the wake width based on the turbine-added TKE, $\delta _{k}$ .

Figure 11. Wake growth rates calculated from $\lambda _{k} = \langle {\textrm {d}\delta _{k}/\textrm {d}x}\rangle$ for (a) $2 \leqslant x\!/\!D \leqslant 7$ , and (b) $15 \leqslant x\!/\!D \leqslant 20$ .

First, the behaviour of $\delta _{k}(x)$ closely mirrors that of $\delta (x)$ . The TKE-based wakes grow nearly linearly in the near field before reaching a plateau, with larger ${\textit{TI}}_{\infty }$ leading to steeper slopes and sharper transitions to the plateau region. Like $\delta$ , $\delta _k$ increases as both $C_T$ and ${\textit{TI}}_{\infty }$ increase, with $\delta _{k,{\textit{High-}}C_T} \geqslant \delta _{k,{\textit{Med-}}C_T} \geqslant \delta _{k, {\textit{Low-}}C_T}$ and $\delta _{k,{{\textit{Group}} 3}} \geqslant \delta _{k,{{\textit{Group}} 2}} \geqslant \delta _{k,{{\textit{Group}} 1}}$ , while ${\mathcal L}_x$ has only a secondary influence. Moreover, the $\lambda _{k[2D-7D]}$ distribution shown in figure 11(a) closely aligns with that of $\lambda _{[2D-7D]}$ in figure 9(a), though with larger values. Hence, fitting the $\lambda _{k[2D-7D]}$ dataset with the same model used for $\lambda _{[2D-7D]}$ yields a good fit ( $R^2=0.931$ ): $\lambda _{k[2D-7D]} = 0.92C_T{\textit{TI}}_{\infty } + 0.037 C_T + 0.004{\mathcal L}$ (grey lines in figure 11 a).

The TKE-based wakes are wider than the velocity deficit-based wakes, $\delta _{k}(x) \geqslant \delta (x)$ , and expand faster, $\lambda _{k[2D-7D]} \geqslant \lambda _{[2D-7D]}$ , with more pronounced differences at high ${\textit{TI}}_{\infty }$ and large $C_T$ . This further emphasises the faster turbulent mixing of the TKE in the wake with the background TKE compared with mass and momentum in the near field, consistent with previous studies on porous and bluff-body wakes (Buxton & Chen Reference Buxton and Chen2023; Lingkan & Buxton Reference Lingkan and Buxton2023). The reduced growth of $\delta _{k}$ mirrors that of $\delta$ , and occurs when the difference in TKE between the wake and the ambient flow becomes shallower, highlighting the important role of $\Delta k$ in driving wake expansion and recovery. Once $\Delta k$ becomes small, both the TKE and velocity deficit expansion rates are reduced, explaining the smaller $\lambda _{k}$ and $\lambda$ in the far field, especially for high- ${\textit{TI}}_{\infty }$ inflows (figure 11 b). Hence, FST intensity accelerates the dissipation of the turbine-added TKE and the recovery of the velocity in the near field. However, the TKE recovers more quickly, eventually reaching a quasi-uniform state for high- ${\textit{TI}}_{\infty }$ inflows. Once $\Delta k \approx 0$ , the recovery of the velocity deficit slows significantly as it propagates through a region of nearly homogeneous TKE, reducing momentum and mass transfer from the background flow into the wake and limiting further wake recovery.

3.3.1. Wake velocity recovery

The influence of FST on the wake velocity recovery is assessed following the approach of Li, Dong & Yang (Reference Li, Dong and Yang2022) and Messmer et al. (Reference Messmer, Hölling and Peinke2024) by radially averaging the time-averaged velocity from the wake centre to the wake width $\delta (x)$ , i.e. $\widetilde {U}(x) = \langle \overline {U}(x,y) \rangle _{\delta (x)}$ . Here, $\widetilde {U}(x)$ is the mean time-averaged velocity within a streamtube of width $\delta (x)$ , with $\widetilde {U}/U_{\infty }$ approaching unity as the wake recovers. Since the power available to a downstream turbine virtually operating in the wake of another scales as $\widetilde {P}_a/P_{\infty } \propto (\widetilde {U}/U_{\infty })^3$ , $\widetilde {U}(x)$ also serves as a measure of wake-induced power loss. In addition, we define $\widetilde {x}$ as the streamwise distance at which the wake recovers to $\widetilde {U}(\widetilde {x}) = 0.9U_{\infty }$ (i.e. $\widetilde {P}_a(\widetilde {x}) = 0.72 P_{\infty }$ ), providing a quantitative – albeit somewhat arbitrary – measure of the near-wake streamwise extent, which we use to compare the different cases.

Figure 12. Streamwise evolution of the wake velocity recovery, $\widetilde {U}/U_{\infty }$ , with a focus on the influence of FST in panel (a), and of $C_T$ in panel (b). Panel (c) shows the streamwise distance, $\widetilde {x}$ , required for the wake to recover to $\widetilde {U}(\widetilde {x}) = 0.9 U_{\infty }$ .

Figure 12 shows $\widetilde {U}(x)$ and $\widetilde {x}$ for all 24 { $C_T$ , FST} combinations. For both group 1 and 2 cases, $\widetilde {U}/U_{\infty }$ initially decreases for $x\!/\!D \leqslant 2$ , reflecting the pressure recovery in the very near wake. As with porous discs, higher $C_T$ increases flow blockage, resulting in a larger pressure drop and a stronger reduction in $\widetilde {U}/U_{\infty }$ immediately downstream of the turbine. For all cases, $\widetilde {U}/U_{\infty }$ increases rapidly in the near field ( $3 \lesssim x\!/\!D \lesssim 7$ ) before transitioning to a slower recovery rate further downstream. The largest differences in $\widetilde {U}/U_{\infty }$ between FST cases are observed in the near field and become more pronounced with increasing $C_T$ . The wake-averaged velocity recovery is significantly enhanced as ${\textit{TI}}_{\infty }$ increases, with a clear distinction between ${\textit{TI}}_{\infty }$ groups: $(\widetilde {U}/U_{\infty })_{{{\textit{Group}} 3}} \geqslant (\widetilde {U}/U_{\infty })_{{{\textit{Group}} 2}} \geqslant (\widetilde {U}/U_{\infty })_{{{\textit{Group}} 1}}$ (for all $C_T$ and $x\!/\!D$ ), and $\widetilde {x}_{ {{\textit{Group}} 3}} \leqslant \widetilde {x}_{ {{\textit{Group}} 2}} \leqslant \widetilde {x}_{ {{\textit{Group}} 1}}$ . Wakes exposed to high- ${\textit{TI}}_{\infty }$ inflows exhibit rapid near-field recovery, as evidenced by the steep $\widetilde {U}$ gradient over the first few diameters, whereas wakes developing in low- ${\textit{TI}}_{\infty }$ inflows recover more gradually. Closer examination of group 2 cases reveals that $\widetilde {U}/U_{\infty }$ deviates from the strict ${\textit{TI}}_{\infty }$ hierarchy, indicating that FST ILS also plays a role in the velocity recovery. For all $C_T$ , $(\widetilde {U}/U_{\infty })_{{M5}} \geqslant (\widetilde {U}/U_{\infty })_{ {L6}}$ within specific streamwise ranges: up to $x\!/\!D \approx 10$ at $C_T\approx 0.5$ , and up to $x\!/\!D \approx 15$ at $C_T \in \{0.7,0.9\}$ , consistent with the earlier observation of $(\Delta U\!/\!U_{\infty })_{{max,M5}} \leqslant (\Delta U\!/\!U_{\infty })_{{max,L6}}$ . Additionally, for $C_T\approx 0.9$ , $(\widetilde {U}/U_{\infty })_{ {L6}}\approx (\widetilde {U}/U_{\infty })_{ {S4}}$ in the near field. Given that ${\textit{TI}}_{\infty , {L6}} \geqslant {\textit{TI}}_{\infty , {M5}} \geqslant {\textit{TI}}_{\infty , {S4}}$ and ${\mathcal L}_{x, {L6}} \geqslant {\mathcal L}_{x, {M5}} \geqslant {\mathcal L}_{x, {S4}}$ , these observations highlight the role of the FST ILS in slowing the recovery of the wake-averaged velocity. Finally, in the near field, $\widetilde {U}/U_{\infty }$ is markedly lower for case L3 than for case S4, despite comparable FST intensities. Whilst the slightly lower ${\textit{TI}}_{\infty }$ in case L3 may partly account for the delayed velocity recovery, the pronounced difference in $\widetilde {U}/U_{\infty }$ between the two cases is likely also a consequence of the larger inflow ILS in L3.

Figure 12(b) highlights the influence of $C_T$ on $\widetilde {U}/U_{\infty }$ across 6 different FST cases. In the near field ( $x\!/\!D \lesssim 10$ ), the recovery rate of $\widetilde {U}/U_{\infty }$ increases substantially with $C_T$ . Further downstream, the $\widetilde {U}/U_{\infty }$ curves nearly collapse, especially in the presence of FST. Larger and prolonged differences in $\widetilde {U}/U_{\infty }$ between the $C_T$ cases are observed in low- ${\textit{TI}}_{\infty }$ inflow conditions (S1 & S2), whereas higher ${\textit{TI}}_{\infty }$ rapidly mitigates the additional velocity deficit induced by higher $C_T$ . Hence, varying $C_T$ primarily modifies the near-field wake-averaged velocity and recovery rate, with a diminishing influence as ${\textit{TI}}_{\infty }$ increases. Figure 12(c) shows that $\widetilde {x}$ decreases dramatically with increasing FST intensity, exhibiting significantly greater sensitivity to ${\textit{TI}}_{\infty }$ than to ${\mathcal L}_x$ and $C_T$ , although $\widetilde {x}$ increases slightly with $C_T$ . For the lowest ${\textit{TI}}_{\infty }$ case, S1, at $C_T \approx 0.9$ , the wake-averaged available power has not yet reached 72 % of the free stream available power $P_{\infty }$ , even at $20D$ , whereas for L8, $\widetilde {x} \leqslant 7$ for all $C_T$ . Generally, in weakly turbulent background flows, $C_T$ variations generate persistent effects on the wake velocity recovery that extend into the far field, whilst in highly turbulent conditions, these effects are rapidly attenuated with FST intensity promoting near-field velocity recovery.

3.3.2. Turbine-added TKE dissipation

Similarly to $\widetilde {U}$ , we define the wake-averaged TKE, $\widetilde {k}(x) = \langle \overline {k}(x,y) \rangle _{\delta (x)}$ . Since the background TKE, $k_{\infty }$ , varies across the FST cases, the recovery of the TKE within the wakes is assessed using the wake-averaged turbine-added TKE, $\Delta \widetilde {k}/U_{\infty }^2=(\widetilde {k} - k_{\infty })/U_{\infty }^{2}$ , with $\Delta \widetilde {k}$ approaching 0 indicating a higher degree of wake TKE recovery. We also introduce $\widetilde {x}_k$ , the TKE-based near-field length, defined as the streamwise distance at which $\Delta \widetilde {k}(\widetilde {x}_k)/U_{\infty }^2 = 0.0015$ . Figure 13 presents $\Delta \widetilde {k}(x)/U_{\infty }^{2}$ and $\widetilde {k}(x)/U_{\infty }^2$ , along with $\widetilde {x}_k$ for all 24 $\{C_T, \textrm {FST}\}$ combinations.

Figure 13. Streamwise evolution of the wake-averaged turbine-added TKE, $\Delta \widetilde {k}/U_{\infty }^2$ (a), and wake-averaged TKE, $\widetilde {k}/U_{\infty }^2$ (b). A focus is placed on the influence of FST in panel (a), and of $C_T$ in panel (b). Panel (c) shows the streamwise distance, $\widetilde {x}_k$ , required for the wake to recover to $\Delta \widetilde {k}(\widetilde {x}_k)/U_{\infty }^2 = 0.0015$ .

Both $\widetilde {k}$ and $\Delta \widetilde {k}$ immediately downstream of the rotor increase with $C_T$ . For $C_T = 0.5$ , both quantities decay for $x\!/\!D \geqslant 1$ , whereas at $C_T \in \{0.7,0.9\}$ , $\widetilde {k}$ and $\Delta {\widetilde {k}}$ first increase with streamwise distance, likely due to the stronger tip shear layer, which enhances turbulence production behind the rotor (see figure 5). As $C_T$ and ${\textit{TI}}_{\infty }$ increase, the streamwise location where $\widetilde {k}$ and $\Delta \widetilde {k}$ begin to decay shifts closer to the turbine, aligning with porous-disc wakes (Li et al. Reference Li, Zhang, Li and Yang2024). As shown in figure 13(a), the decay of $\Delta \widetilde {k}$ in case L3 () begins further downstream compared with cases with similar ${\textit{TI}}_{\infty }$ but smaller ${\mathcal L}_x$  – S4 () and M5 () – suggesting that the TKE recovery onset is delayed when increasing the inflow ILS, though the lowest ${\textit{TI}}_{\infty }$ for L3 may partly explain this delay. Larger differences in $\widetilde {k}$ between the $C_T$ cases persist in the far field in low- ${\textit{TI}}_{\infty }$ inflow conditions (e.g. see cases S1 and S2 in figure 13 b), highlighting the prolonged sensitivity of the TKE recovery to $C_T$ variations in weakly turbulent ambient flows.

For all $C_T$ , the maximum $\Delta \widetilde {k}$ follows the order: $(\Delta \widetilde {k}/U_{\infty }^2)_{ {\textit{max},\textit{Group} 3}} \geqslant (\Delta \widetilde {k}/U_{\infty }^2)_{{\textit{max},\textit{Group} 2}} \geqslant (\Delta \widetilde {k}/U_{\infty }^2)_{ {\textit{max},\textit{Group} 1}}$ , although it does not strictly follow the hierarchical order of increasing ${\textit{TI}}_{\infty }$ , due to the secondary influence of $C_T$ and ${\mathcal L}_x$ . The recovery rate of $\Delta \widetilde {k}$ is largely a function of ${\textit{TI}}_{\infty }$ , with the fastest recovery in case L8 and the slowest in case S1. As previously observed in the TKE profiles, $\Delta \widetilde {k}\approx 0$ for case L8 at $x\!/\!D \gtrsim 15$ across all three $C_T$ cases. Focusing on L# cases, $\Delta \widetilde {k}/U_{\infty }^2$ follows a hierarchical order corresponding to decreasing ${\textit{TI}}_{\infty }$ after a few diameters, i.e. $(\Delta \widetilde {k}/U_{\infty }^2)_{ {L8}} \leqslant (\Delta \widetilde {k}/U_{\infty }^2)_{ {L7}} \leqslant (\Delta \widetilde {k}/U_{\infty }^2)_{ {L6}} \leqslant (\Delta \widetilde {k}/U_{\infty }^2)_{{L3}}$ (for all $C_T$ ), with a similar trend observed for S# cases. This clearly illustrates that the recovery of the turbine-added TKE is enhanced with increasing ${\textit{TI}}_{\infty }$ . The local recovery rate also varies as the wake mixes with the background flow and $\Delta \widetilde {k}$ decays. The TKE recovery is accelerated in the near field for high- ${\textit{TI}}_{\infty }$ and high- $C_T$ cases, driven by enhanced mixing resulting from both higher FST intensity and a greater initial $\Delta \widetilde {k}$ , whilst the recovery is more gradual for low- ${\textit{TI}}_{\infty }$ and low- $C_T$ cases.

Focusing on group 2 FST cases – L6 (), M5 () and S4 () – it is observed that for all $C_T$ , $(\Delta \widetilde {k}/U_{\infty }^2)_{{L6}} \geqslant (\Delta \widetilde {k}/U_{\infty }^2)_{{M5}} \geqslant (\Delta \widetilde {k}/U_{\infty }^2)_{ {S4}}$ for $x\!/\!D \gtrsim 5$ (figure 13 a). This trend may seem counter-intuitive, as one might expect the opposite given the earlier conclusion that higher ${\textit{TI}}_{\infty }$ promotes the faster decay of the turbine-added TKE. However, given that ${\mathcal L}_{x,{L6} } \approx 2{\mathcal L}_{x,{M5}}\approx 4{\mathcal L}_{x,{S4}}$ , this suggests that larger ILS slows the TKE recovery for inflows with nearly identical ${\textit{TI}}_{\infty }$ . Moreover, the substantially larger $\Delta \widetilde {k}/U_{\infty }^2$ for case L3 () compared with case S4 (), despite both cases having nearly identical ${\textit{TI}}_{\infty }$ , further reinforces that the TKE recovery is delayed and slower as the inflow ILS increases.

Finally, the TKE-based near-field length $\widetilde {x}_k$ increases with $C_T$ due to greater initial turbine-added TKE, but decreases substantially with increasing ${\textit{TI}}_{\infty }$ (figure 13 c). Comparison of group 2 cases reveals that $\widetilde {x}_k$ increases with ${\mathcal L}_x$ – $\widetilde {x}_{k, {L3}} \geqslant \widetilde {x}_{k,{L6,M5}} \geqslant \widetilde {x}_{k, {S4}}$ – confirming the slower recovery of the turbine-added TKE when increasing the background ILS.