3.1. Time-averaged streamwise velocity

The non-dimensional time-averaged velocity (U ⁺ ) in the direction of flow can be estimated using

(1) \begin{equation} U^{+}=\frac{\frac{1}{n}\sum\limits_{i=1}^{n}U_{i}}{U_{*}}, \end{equation}

where n defines the number of samples recorded at individual measurement locations and U _i depicts the instantaneous velocity measured in the longitudinal direction of flow. To compare the flow patterns, the instantaneous velocity readings of all the sections along the length of the dune are normalised with a constant value of shear velocity U _* (= 2.97 cm s⁻¹), estimated at the dune’s crest portion. The value of shear velocity obtained at the crest portion is estimated using the turbulent kinetic energy method in the near-bed region (z/h < 0.25) (Taye and Kumar, Reference Taye and Kumar2021). Figure 3 illustrates the variation of non-dimensional streamwise velocity at some critical sections along the length of the mobile dune.

Figure 3. Variation of non-dimensional (a) streamwise velocity at some critical sections of the dune and (b) streamwise velocity with error plot.

At the initial section, the velocity profile shows a steady and continuous increase with depth towards the surface of the water. The negative value of streamwise velocity in the near-bed region at the dune’s initial sections confirms the flow circulation due to a strong wake effect from an upstream dune. In the middle sections (40 and 70 cm) on the stoss side of the dune, the streamwise velocity increases more rapidly in the region z/h< 0.4, confirming enhanced shear and acceleration of flow as it ascends the dune slope. The velocity profile at 77 cm shows a similar trend, with maximum velocity observed in this zone, reflecting further flow adjustment and momentum gain.

At the lee side section of the dune, the streamwise flow velocity is lower as compared with the velocity at the crest section, indicating a recirculation or wake zone resulting from flow separation at the dune crest and the subsequent reattachment process downstream. While this zone exhibits typical post-crest flow behaviour, an important observation is that the streamwise velocity in the near-bed region on the lee side of the considered dune is higher than at the initial section. This suggests that the wake generated by the preceding dune (influencing the initial section) is stronger than the wake formed at the lee side of the current dune.

3.2. Reynolds shear stress

A higher Reynolds shear stress (RSS) value at a given location in the flow field depicts greater momentum exchange within the flow. Studies have revealed that bed features in the flow field cause higher Reynolds stress patterns, leading to higher momentum exchange (Bernard and Handler, Reference Bernard and Handler1990). The plot of non-dimensional RSS against the normalised vertical position (z/h) at various sections along the dune reveals the spatial variability in turbulent momentum flux, as shown in Figure 4. The momentum flux influences sediment entrainment, transport and deposition, providing insights into bedform evolution (Järvelä, Reference Järvelä2005; Yang & Choi, Reference Yang and Choi2009; Huai et al., Reference Huai, Zhang, Katul, Cheng, Tang and Wang2019). The non-dimensional RSS (τ _uw ) in the flow can be presented by

(2) \begin{equation} \overline{u'w'}^{+}=\frac{-\rho _{w}\overline{u'w'}}{\rho _{w}\left(U_{\ast }^{\mathit{2}}\right)} \end{equation}

where u^′ and w^′ are the fluctuating components associated with the flow in streamwise and vertical directions, respectively, and ρ _w is the density of water.

Figure 4. Variation of non-dimensional (a) RSS at some critical sections of the dune, (b) RSS with error plot.

At the initial section (0 cm) and the lee-side section (77 cm) of the dune, the RSS is observed to be relatively high. The magnitude of the RSS is maximum at 0.2 < z/h < 0.4 and in the near-bed region. The observation indicates intense turbulent mixing and strong momentum exchange between the flow layers in the initial sections. Physically, this elevated turbulence near the bed enhances the ability of the flow to entrain and transport sediment particles, contributing to bedform initiation and mobility. The shear stress distribution suggests a well-developed turbulent boundary layer that actively interacts with the mobile bed, potentially initiating sediment.

The patterns of RSS at the middle sections (40 and 70 cm) exhibit moderate values, with peaks more concentrated in the near-bed regions. This trend implies that the flow is adjusting to the evolving bedform geometry. As the flow traverses the dune, sediment particles already in motion may continue to be transported, but the capacity for fresh sediment entrainment diminishes slightly due to reduced shear intensities towards the end sections of the stoss side of the dune. This could represent a zone of transitional sediment transport, where the morphology begins to stabilise and the flow gradually approaches an equilibrium condition with the bedform.

RSS at the crest portion of the dune is featured by a sharp peak near the water’s surface. In the near-bed region, the trend exhibits the lowest values, with a flatter and less structured profile and a flattened trend. This value suggests that sediment motion at the crest portion is not as profound as in the region of the lee-side sections or the initial sections. However, localised erosion at the crest portion may occur, reshaping the crest and contributing to the dune’s downstream migration.

3.3. Turbulent intensities

Turbulent intensity determines the contribution of fluctuating velocity components in the streamwise, spanwise and vertical flow directions. A higher turbulent intensity corresponds to higher turbulence in the flow field. Non-dimensional turbulent intensities in the streamwise (σ _u ⁺ ), spanwise (σ _v ⁺ ) and vertical (σ _w ⁺ ) directions are given by (3)–(5), respectively:

(3) \begin{equation} {\sigma _{u}}^{+}=\frac{\sqrt{\frac{\sum _{i=1}^{n}\left(U{i}^{}{-}{}U\right)^{2}}{n-1}}}{U_{*}}, \end{equation}

(4) \begin{equation} {\sigma _{v}}^{+}=\frac{\sqrt{\frac{\sum _{i=1}^{n}\left(V{i}^{}{-}{}V\right)^{2}}{n-1}}}{U_{*}}, \end{equation}

(5) \begin{equation} {\sigma _{w}}^{+}=\frac{\sqrt{\frac{\sum _{i=1}^{n}\left(W{i}^{}{-}{}W\right)^{2}}{n-1}}}{U_{*}}, \end{equation}

where u^′ , v^′ and w^′ are the fluctuating components associated with the flow in streamwise, lateral and vertical directions, respectively.

Figures 5(a)–5(c) show the distribution of non-dimensional turbulence intensities in the streamwise, spanwise and vertical directions, respectively.

Figure 5. (a) Variation of non-dimensional (i) streamwise turbulent intensity at some critical sections of the dune, (ii) streamwise turbulent intensity with error plot. (b) Variation of non-dimensional (i) spanwise turbulent intensity at some critical sections of the dune, (ii) spanwise turbulent intensity with error plot. (c) Variation of non-dimensional (i) vertical turbulent intensity at some critical sections of the dune, (ii) vertical turbulent intensity with error plot.

Among the three components of turbulent intensity, the streamwise turbulence intensity is most pronounced in the flow as compared with the turbulent intensity in the vertical and spanwise directions. At the initial section (0 cm) and middle section (40 cm) of the dune, high values are observed in the region of 0.25 < z/h < 0.45. In the region near the crest portion (70 cm) and at the crest portion sections (77 cm), the elevated turbulence intensities in the near-bed region indicate strong fluctuations in the streamwise velocity component, a direct consequence of flow acceleration over the rising bedform. The lee-side section shows significantly higher streamwise turbulence intensity, reflecting a region of intense mixing due to the formation of a scour hole. This spatial variability illustrates how the dune’s shape governs the distribution of shear stress and, consequently, the erosion and deposition zones.

Similar to the streamwise velocity pattern, at the dune’s initial section (0 cm), the magnitude of lateral turbulent intensity is higher in the region of 0.25 < z/h < 0.45. It exhibits moderate values across the middle sections, indicating lateral instabilities induced by the three-dimensional structure of the bedform. These spanwise fluctuations contribute to the redistribution of sediment perpendicular to the main flow direction, facilitating the maintenance of the dune’s transverse geometry and enhancing mixing. However, spanwise turbulence increases in the near-bed region of the crest portion and the lee-side section, reinforcing higher energy dissipation in the flow due to the development of scour holes on the lee-side section of the dune.

The magnitude of vertical turbulence intensity is the lowest among the three turbulent intensities. Across all sections, vertical turbulence remains relatively uniform, showing only minor variations among the different bedform positions. This suggests a more consistent vertical momentum exchange throughout the flow field. However, slightly higher vertical turbulence in the near-bed region of the crest portion and the lee-side sections indicates localised upward bursts and turbulent events capable of lifting particles.

3.4. Octant analysis of bursting events

Octant analysis quantifies different bursting events associated with the turbulent characteristics of flow into eight bursting events as follows.

1. 1. Class I-A, Internal outward interaction (u^′ > 0, v^′ > 0, w^′ > 0).

2. 2. Class II-A, Internal ejection (u^′ < 0, v^′ <0 , w^′ > 0).

3. 3. Class III-A, Internal inward interaction (u^′ < 0, v^′ < 0, w^′ < 0).

4. 4. Class IV-A, Internal sweep (u^′ > 0, v^′ > 0, w^′ < 0).

5. 5. Class I-B, External outward interaction (u^′ > 0, v^′ < 0, w^′ > 0).

6. 6. Class II-B, External ejection (u^′ < 0, v^′ > 0, w^′ > 0).

7. 7. Class III-B, External inward interaction (u^′ < 0, v^′ > 0, w^′ < 0).

8. 8. Class IV-B, External sweep (u^′ > 0, v^′ < 0, w′ < 0).

The occurrence probability of each event can be defined as (Keshavarzi and Gheisi, Reference Keshavarzi and Gheisi2006)

(6) \begin{equation} P_{k}=\frac{n_{k}}{N}, \end{equation}

where $N=\sum _{k=1}^{{8}}n_{k},\quad k=1,2,3,4\ldots ,8.$ .

Here, P _k is the occurrence probability of each event, n _k is the number of events in each class and N is the total number of bursting events. Figure 6 represents the occurrence probability of different bursting events across the dune.

Figure 6. Occurrence probability of bursting events along the dune.

The probabilities of occurrence of internal outward interaction (Class I-A) and external outward interaction (Class I-B) events are low to moderate probability (∼6 %–12 %) across the dune length. The probability of occurrence of I-A has slightly higher intensity in the near-bed region and upstream dune face, while I-B shows localised stronger events near the crest. The findings suggest that outward interactions are less dominant, contributing minimally to strong Reynolds stress generation. However, the probabilities of occurrence of both inward and outward ejection (Class II-A and Class II-B) events are higher. The inward and outward ejection (Class II-A and Class II-B) events dominate at the crest portion and lee-side sections of the dune and stoss side. The study also confirms that ejection events (upward motion of low-momentum fluid) are major contributors to turbulence in the wake zone located at the lee side of the dune.

The internal and external inward interaction (Class III-A, Class III-B) shows lower probabilities of occurrence throughout the flow field along the length of the dune. Although some localised peaks in the occurrence of internal inward interaction (Class III-A) can be observed in mid-depth regions and external inward interaction (Class III-A, Class III-B) can be observed near the crest location, the dominance of this event is less. However, the probabilities of occurrence of an internal sweep event (Class IV-A) are very strong near the bed and stoss side, showing strong downward momentum transport in the near region at the initial section and the lee-side section of the dune, which will enhance sediment transport behaviour. Further, a very strong dominance external sweep event (Class IV-B) can be observed at the dune crest, which suggests dune crest movement along the flow direction leading to overall bedform migration. The results confirm that sweeps (downward rush of high-momentum fluid) dominate in the near-bed region of the initial section, crest portion and lee-side section of the dune, confirming strong turbulence production, which is crucial for sediment entrainment.

3.5. Probability distribution functions

P.d.f.s in turbulence represent the likelihood of observing a specific value of a fluctuating quantity over time, which helps quantify turbulence’s randomness and chaotic nature. Mathematically, for a random variable x, the p.d.f. f(x) satisfies

(7) \begin{equation} P\left(x_{1}\lt x\lt x_{2}\right)=\int\limits_{x_{1}}^{x_{2}}f\!(x)\, \text{d}x, \end{equation}

where x represents the velocity fluctuations or turbulent shear stress. Details about the probability distribution function of fluctuating components and RSS, along with the equation to evaluate it, are provided by Sharma and Kumar (2017) and Gurugubelli et al. (Reference Gurugubelli, Timbadiya and Barman2025).

3.5.1. Probability function of fluctuating component

Figure 7 depicts the p.d.f. of streamwise velocity fluctuations (P _u ) plotted against the normalised velocity fluctuation ( $\hat{u}$ ) at some critical sections along a dune. At the initial section (0 cm), the experimental data are relatively well-aligned with the theoretical curve, with a peak value of approximately 0.35. However, there is some scatter in the tails, especially in the positive range. These results suggest that although extreme velocity fluctuation events characterise this section, the flow is adjusting to the presence of the bedform.

Figure 7. Probability distribution of streamwise velocity fluctuations.

The experimental data in the middle sections of the dune start to deviate more from the theoretical prediction, with an observable right-skewness in the distribution. This asymmetry signifies stronger turbulent interactions and the amplification of flow instabilities due to a steepening slope and streamline convergence, which elevate the likelihood of high-magnitude streamwise velocity fluctuations. The agreement between theoretical and experimental data further deteriorates at the crest portion. The experimental curve is broader and flatter, indicating increased turbulence intensity and a higher probability of positive and negative velocity fluctuations.

At the lee-side section, where flow separation and reattachment dominate, the experimental p.d.f. closely follows the theoretical prediction near the peak, but some spread persists in the tails. This pattern suggests that although the mean flow becomes more symmetric, the region still experiences intermittent turbulent structures, such as vortices and eddies, contributing to deviations from idealised distributions. The p.d.f. of lateral velocity fluctuations (P _v ) against the normalised lateral velocity fluctuation ( $\hat{v}$ ) across different sections of the dune profile is shown in Figure 8.

Figure 8. Probability distribution of spanwise velocity fluctuations.

The dune’s initial section (0 cm) is characterised by a symmetric distribution about the mean, which aligns fairly well with the theoretical curve. The close match indicates less disturbed lateral flow in this upstream region. Lateral velocity fluctuations are minimal here, showing weak cross-stream turbulent activity. However, in the middle sections, the experimental data diverge slightly from the theoretical distribution, particularly in the positive fluctuation range. Evidence of a subtle increase in asymmetry indicates enhanced lateral movement due to the evolving boundary layer and interaction with the dune slope. Turbulence begins to develop more strongly, influencing the lateral component of velocity due to turbulent mixing and lateral transport, influenced by pressure gradients and flow convergence on the stoss side of the dune.

Similarly, the asymmetry at the crest portion widens further and becomes flatter than the theoretical distribution, indicating high turbulence intensity in the lateral direction. The enhanced lateral fluctuations here are physically significant, as they suggest the possible formation of lateral eddies and swirling motions, which can affect sediment suspension and redistribution. The experimental p.d.f. regains better agreement with the theoretical curve at the lee-side section, especially near the centre. The reduction in fluctuation intensity suggests a restabilisation of the flow in the lateral direction. Although residual turbulence remains from upstream interactions, the flow in the lateral direction becomes relatively more symmetric and less chaotic, which is reflected in the closer match to the theoretical p.d.f.

Figure 9 represents the distributions of the p.d.f. of vertical velocity fluctuations (P _w ) against the normalised vertical velocity fluctuation ( $\hat{w}$ ) at some critical sections over a dune-shaped bedform.

Figure 9. Probability distribution of vertical velocity fluctuations.

The theoretical distributions generally exhibit a sharply peaked shape centred at zero, resembling a Laplace or exponential type distribution, indicating the assumption of symmetric and less variable vertical motions in the model. However, the experimental data deviate from the theoretical trend, especially in the middle and downstream sections, showing broader tails and occasional skewness. The experimental values deviate towards the positive side at the dune’s initial and lee-side sections, suggesting asymmetric vertical velocity. The experimental p.d.f. shows broad tails, underscoring the turbulent and chaotic flow in these regions due to vortex shedding, which can enhance the sediment’s vertical motion and initiate sediment transport.

However, in the middle sections of the dune, the experimental distribution becomes more symmetric with the theoretical curve, reflecting reduced vertical motions caused by the influence of the upstream dune slope. The spread of the patterns slightly narrows, indicating a partial recovery of flow stability in these regions. The crest region displays the most significant deviations between experimental and theoretical curves. The experimental p.d.f. is markedly wider, revealing strong vertical fluctuations and coherent turbulent structures.

3.5.2. Probability function of RSS

Figure 10 presents comparative plots of the probability density function of Reynolds shear stress (P _τ ) against normalised shear stress ( $\hat{\tau }$ ) at some critical sections of the dune. It was observed that at different sections along the dune-shaped bedform, the theoretical distribution exhibits a sharp peak at $\hat{\tau }$ = 0, indicating the dominance of low-magnitude shear stress events, which is commonly observed over the alluvial bedform. However, the experimental data show varying degrees of agreement with the theoretical distribution depending on the position along the dune profile.

Figure 10. Probability distribution of RSS.

At the initial (0 cm) and the lee-side sections of the dune, the plot of experimental distribution function aligns well with the theoretical curve on the negative side of $\hat{\tau }$ , but shows noticeable deviation on the positive side, suggesting asymmetries in shear stress behaviour. These dune sections display the most significant deviation between theoretical and experimental results in the positive range, representing significant flow separation and recirculation zones. The findings suggest that turbulence is highly anisotropic and disorganised due to vortex shedding. The wide scatter in experimental values indicates an abundance of energetic turbulent structures that simplified theoretical models do not capture well.

However, at the middle sections (40 and 70 cm), the correlation between experimental and theoretical distributions improves, particularly near the peak and left tail, though some divergence is still visible on the positive side. This improvement indicates the progressive development of shear layers along the stoss side of the dune as the flow accelerates along the dune and becomes more turbulent. The theoretical and experimental curves remain similar at the dune’s crest, but the experimental data again show considerable spread on the positive side, signifying the onset of flow separation and strong shear layer formation.

3.6. Higher-order structure functions

In a turbulent flow field, higher-order structure functions are statistical tools used to quantify the differences in velocity across varying spatial scales. They are critical to understanding the multi-scale nature of turbulence and provide a robust framework for characterising the strength and scale of intermittent events.

The nth-order structure function can be defined as

(8) \begin{equation} S_{n}\!\left(r\right)=\left\langle \left| \delta _{u}\!\left(r\right)\right| ^{n}\right\rangle =\left\langle \left| u\!\left(x+r\right)-u\left(\!x\right)\right| ^{n}\right\rangle, \end{equation}

where u(x) is the velocity at position x, δ _u (r) is the velocity increment over distance r and n is the order of the moment. While second-order structure functions (S ₂(r)) relate to the energy spectrum, higher-order structure functions (n > 3) provide information on intermittency and non-Gaussian features of turbulence, especially in the small-scale dissipative range. Figure 11 presents the variation of the higher-order velocity fluctuation in the streamwise direction with the non-dimensional flow depth (z ⁺) across different flow sections over a dune-shaped mobile bedform. Here, $z^{+}=(zu_{*})/\nu$ is the non-dimensional distance from the bed surface of the dune.

Figure 11. Variation of the higher-order velocity function at some critical sections of the dune.

Higher-order structure functions reveal the evolving nature of turbulent bursts, coherent structures and energy transfer mechanisms influenced by bedform topography. A general pattern is observed where the magnitude of the structure–function increases with higher orders of 2p, at all the sections. These patterns indicate a stronger contribution from intermittent turbulent events and extreme velocity fluctuations. At the initial section (0 cm), the structure–function values are relatively modest across all orders, reflecting a less developed turbulent field. However, in the near-bed region of the initial section, the magnitudes are observed to be on the higher side, suggesting extreme velocity fluctuations due to flow circulation. Similar to the initial section, in the middle section on the stoss side of the dune, an increase in the magnitude of the structure functions was observed in the near-bed region. This implies a stronger turbulent interaction, likely caused by flow acceleration and increased shear stress as the flow climbs the stoss side of the dune. At the 70 cm section, the structure–function values continue to rise, particularly towards the surface of the flow, indicating enhanced turbulence and intermittency near the surface of the water rather than in the near-bed region at these locations.

The crest portion exhibits the highest structure function values, but is only confined towards the surface of the flow. On the lee-side section, the structure–function patterns exhibit the highest value, particularly in the wake region, confirming vortex shedding and maximum energy dissipation, generating complex and fluctuating turbulent behaviour in this region due to the development of scour holes. The sharp peaks in the structure–function curves at the lee-side section suggest the presence of intense turbulent bursts and strong nonlinear interactions. Thus, the structure–function analysis across the dune highlights a progression in turbulence intensity and intermittency in all the sections on the stoss side of the dune and redistribution on the lee side. These findings suggest the strong influence of bedform topography on turbulent flow structure, highlighting the importance of spatially resolved turbulence measurements in understanding sediment transport and flow dynamics over mobile beds.

3.7. Morphological patterns of the mobile bedforms

In addition to the experimental assessment of turbulence characteristics over mobile bedforms, the study also examines the morphological evolution of the bedform shape. Bedform morphology along the dune length was analysed using URS (ultrasonic ranging system). Four morphological profiles of the bedform surface were recorded at 8-hour intervals. Figure 12 illustrates how the change in bedform morphology changes with time.

Figure 12. (a) Change in bedform morphology changes with time and (b) error plot.

The findings indicate a progressive increase in the maximum scour depth at the lee side of the dune. Initially, the depth from the water surface was 13 cm, gradually increasing to 13.5, 14.5 cm and eventually 14.8 cm over the observation period. Similarly, due to sediment being eroded from the crest region and transported downstream, the dune’s crest migrated, increasing the distance from the water surface. Initial readings suggest the distance of the dune crest from the water surface to be below 9.5 cm, which increased to 10 cm at 8 h and approximately 10.8 cm at 24 h. This crest movement contributes to developing more sinuous, three-dimensional bedform features with time. Sediment transport in the river system with dunes primarily occurs due to sediment motion from the stoss side (upstream face) of the dune and the development of scour holes on the lee side, facilitating dune migration in the direction of the flow. Figure 13 depicts the change in depth of crest and scour, along with the volume of sediment transport over the experimental run.

Figure 13. (a) Volume of sediment transport and (b) depth of bed surface from water surface over the experimental run.

During the first 8 hours, sediment transport was notably high, reaching ∼2722 cm³. However, after the 16-h mark, the volume of sediment transport decreased to 1986 cm³. At the end of 24 hours, the transported sediment volume further reduced to 521 cm³, suggesting that the dune bedform was approaching an equilibrium state, beyond which significant sediment motion would likely cease with time. The experimental results highlight a clear trend of increasing scour depth and crest elevation with time, pointing to active morphological evolution of the mobile bedform. The sediment transport volumes observed suggest that the dune undergoes an initial phase of high mobility, which diminishes over time as the system approaches equilibrium.

At the 24-h observation period, the amount of sediment transported was estimated to be ∼521 cm³, highlighting that the dune bedform is on the verge of achieving equilibrium conditions. The results obtained from estimating the amount of sediment transport indicate that downward seepage significantly enhances sediment transport. As the downward seepage rate increases, the cumulative amount of sediment transported also increases, leading to a higher speed of bedform migration.