Observations of dune interactions from DEMs using through-water Structure from Motion

Scheltinga, Renske C. Terwisscha van; Coco, Giovanni; Kleinhans, Maarten G.; Friedrich, Heide

doi:10.1016/j.geomorph.2020.107126

Cited by 16 publications

(24 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Simultaneous splitting and merging are shown in M2 and S2. This phenomena are assumed to be closely related to cross‐stream bedform propagation, that is, lateral linking (Kocurek et al., 2010; van Scheltinga et al., 2020). Figure 16c quantifies spanwise directionality, defined as the ratio of spanwise to streamwise velocity v b / u b , obtained by the BIV technique.…”

Section: Discussionmentioning

confidence: 99%

“…The coupling among migrating bedforms, shear stress, and turbulent structures is highlighted in (i) the streamwise velocity power spectrum showing slow temporal modulation of the near wall velocity (Khosronejad & Sotiropoulos, 2014; Singh et al., 2010; Sotiropoulos & Khosronejad, 2016), and (ii) in the coherent vortical structures resulting from flow separation over two‐ and three‐dimensional crests (Best, 2005; Maddux, 2003b; Parsons et al., 2005; Swanson et al., 2018; van Scheltinga et al., 2020). Those flow structures are found to significantly influence the geometry of downstream bedforms, suggesting a cyclical modulation exists among flow structures, local bed shear stress, sediment transport, and bedform morphology (Jerolmack & Mohrig, 2005a; Kocurek et al., 2010; van Scheltinga et al., 2020). Such interaction has a visible impact on the spatial heterogeneity of sediment deposits, as discussed in Galeazzi et al.…”

Section: Introductionmentioning

confidence: 99%

“…A systematic identification and statistical characterization of bedform morphology and kinematics have been a great challenge due to the multi‐scale interaction between the evolving bathymetry and the turbulent flow (Bennett & Best, 1995; Best, 2005; Best & Kostaschuk, 2002; Kwoll et al., 2017, 2016; Maddux et al., 2003a, 2003b; Nelson et al., 1995; Jerolmack & Mohrig, 2005a). The coupling among migrating bedforms, shear stress, and turbulent structures is highlighted in (i) the streamwise velocity power spectrum showing slow temporal modulation of the near wall velocity (Khosronejad & Sotiropoulos, 2014; Singh et al., 2010; Sotiropoulos & Khosronejad, 2016), and (ii) in the coherent vortical structures resulting from flow separation over two‐ and three‐dimensional crests (Best, 2005; Maddux, 2003b; Parsons et al., 2005; Swanson et al., 2018; van Scheltinga et al., 2020). Those flow structures are found to significantly influence the geometry of downstream bedforms, suggesting a cyclical modulation exists among flow structures, local bed shear stress, sediment transport, and bedform morphology (Jerolmack & Mohrig, 2005a; Kocurek et al., 2010; van Scheltinga et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Scale‐Dependent Bedform Migration and Deformation in the Physical and Spectral Domains

2021

View full text Add to dashboard Cite

Multi-scale bathymetries observed in laboratory channels and natural rivers have posed several challenges to the description of bedform geometry and kinematics. To better quantify scaledependent migration velocity, high resolution spatio-temporal bed evolution data are analyzed using three independent methods: (i) a bedform tracking method that identifies individual bedforms in longitudinal bed elevation profiles, (ii) a cross-correlation based, image matching technique in consecutive bathymetry scans similar to Particle Image Velocimetry, and (iii) two-dimensional frequency-wavenumber spectra marking a dispersion relation between bedform period and length, allowing estimation of Fourier-based, scale-dependent migration velocities. The comparative studies show that the spectral and bedform tracking methods present small differences in the migration velocity of medium-large bedforms. However, significant deviations occur in the small bedforms, mostly due to bedform sheltering or amplified exposure to the flow, which also contribute to their enhanced scale-dependent deformation. The analysis also shows that some form of scale separation is needed to extract the large and slowly migrating bedforms as they are masked by secondary features when several bedform orders coexist. Bathymetric Image Velocimetry reasonably estimates the averaged migration velocity and exhibits potential to study relations between spanwise bed surface velocity and local bedform kinematics. LEE ET AL.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Scale‐Dependent Bedform Migration and Deformation in the Physical and Spectral Domains

2021

View full text Add to dashboard Cite

show abstract

“…Despite this, the existing studies have analyzed the susceptibility of landslides using a single time-related data source without considering whether the date of the data source is consistent with the study date [57,58]. Therefore, it is necessary to understand the temporal evolution of influencing factors (e.g., topography) and the influencing mechanisms of the factors on the susceptibility assessment [59,60]. The changes in influencing factors are significant in earthquake-and landslide-prone areas [61], such as the study area.…”

Section: Advantages and Limitationsmentioning

confidence: 99%

Exploring the Impact of Multitemporal DEM Data on the Susceptibility Mapping of Landslides

Wang

Han

et al. 2020

Applied Sciences

View full text Add to dashboard Cite

Digital elevation models (DEMs) are fundamental data models used for susceptibility assessment of landslides. Due to landscape change and reshaping processes, a DEM can show obvious temporal variation and has a significant influence on assessment results. To explore the impact of DEM temporal variation on hazard susceptibility, the southern area of Sichuan province in China is selected as a study area. Multitemporal DEM data spanning over 17 years are collected and the topographic variation of the landscape in this area is investigated. Multitemporal susceptibility maps of landslides are subsequently generated using the widely accepted logistic regression model (LRM). A positive correlation between the topographic variation and landslide susceptibility that was supported by previous studies is quantitatively verified. The ratio of the number of landslides to the susceptibility level areas (RNA) in which the hazards occur is introduced. The RNA demonstrates a general decrease in the susceptibility level from 2000 to 2009, while the ratio of the decreased level is more than fifteen times greater than that of the ratio of the increased level. The impact of the multitemporal DEM on susceptibility mapping is demonstrated to be significant. As such, susceptibility assessments should use DEM data at the time of study.

show abstract

“…To account for these effects, new approaches for predicting dune orientation are needed that will provide a basis for deriving improved parameterizations of the deviation between the depth-averaged and near-bed flow. However, this task is difficult to accomplish a priori (e.g., Weij, 2012), as dune orientation is often a product of the interplay between bed slope, spatially nonhomogeneous sediment transport rates (Rubin, 2012;Terwisscha van Scheltinga et al, 2020;Unsworth et al, 2016;Weij, 2012), and the interaction that dunes have on the mean flow field.…”

Section: 1029/2020jf005571mentioning

confidence: 99%

Influence of Dunes on Channel‐Scale Flow and Sediment Transport in a Sand Bed Braided River

et al. 2020

View full text Add to dashboard Cite

Current understanding of the role that dunes play in controlling bar and channel-scale processes and river morphodynamics is incomplete. We present results from a combined numerical modeling and field monitoring study that isolates the impact of dunes on depth-averaged and near-bed flow structure, with implications for morphodynamic modeling. Numerical simulations were conducted using the three-dimensional computational fluid dynamics code OpenFOAM to quantify the time-averaged flow structure within a 400 m × 100 m channel using digital elevation models (DEMs) for which (i) dunes and bars were present within the model and (ii) only bar-scale topographic features were resolved (dunes were removed). Comparison of these two simulations shows that dunes enhance lateral flows and reduce velocities over bar tops by as much as 30%. Dunes influence the direction of modeled sediment transport at spatial scales larger than individual bedforms due to their effect on topographic steering of the near-bed flow structure. We show that dunes can amplify, dampen, or even reverse the deflection of sediment down lateral bar slopes, and this is closely associated with 3-D and obliquely orientated dunes. Sediment transport patterns calculated using theory implemented in depth-averaged morphodynamic models suggest that gravitational deflection of sediment is still controlled by bar-scale topography, even in the presence of dunes. However, improved parameterizations of flow and sediment transport in depth-averaged morphodynamic models are needed that account for the effects of both dune-and bar-scale morphology on near-bed flow and sediment transport.

show abstract

Observations of dune interactions from DEMs using through-water Structure from Motion

Cited by 16 publications

References 59 publications

Scale‐Dependent Bedform Migration and Deformation in the Physical and Spectral Domains

Scale‐Dependent Bedform Migration and Deformation in the Physical and Spectral Domains

Exploring the Impact of Multitemporal DEM Data on the Susceptibility Mapping of Landslides

Influence of Dunes on Channel‐Scale Flow and Sediment Transport in a Sand Bed Braided River

Contact Info

Product

Resources

About