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Journal ArticleDOI

The effect of geometry and bottom friction on local bed forms in a tidal embayment

G. P. Schramkowski1, Henk M. Schuttelaars1, H.E. de Swart1
Utrecht University1
01 Jul 2002-Continental Shelf Research (CONTINENTAL SHELF RESEARCH)-Vol. 22, Iss: 11, pp 1821-1833
TL;DR: In this paper, a 2DH idealized local morphodynamic model for a tidal channel was used to demonstrate that estuarine bars with typical length scales on the order of the tidal excursion length can develop as the result of a positive feedback between water motion, sediment transport and the sandy bottom.
About: This article is published in Continental Shelf Research.The article was published on 2002-07-01 and is currently open access. It has received 75 citations till now. The article focuses on the topics: Length scale & Suspended load.

Summary (3 min read)

Jump to: [1. Introduction][2. Model description][3. Linear stability analysis][4. Results][4.1. Advective instabilities for linear bottom friction][4.2. Bedslope effects][4.3. Non-linear friction and the influence of channel width] and [5. Discussion and conclusions]

1. Introduction

  • The geomorphology of semi-enclosed tidal embayments with a sandy bed often consists of a complex network of channels and shoals.
  • On the other hand, deeper embayments, e.g. those located in the Dutch and German Wadden Sea, are characterized by a fractal pattern of channels (cf. Cleveringa and Oost, 1999; Ehlers, 1988) which appear to scale with the length of the embayment.
  • Their model results apply to narrow, frictionally dominated tidal channels.
  • The results from the two approaches should qualitatively agree in the appropriate limits.
  • Here, the intermediate model will be compared with the results by Seminara and Tubino (1998).

2. Model description

  • The features studied in this paper have length scales which are small compared with the tidal wavelength, the embayment length and the length scale on which variations of the channel width occur.
  • Within the local model, tidal velocities are of the order of 1 m s 1: Since the amplitude of the sea surface elevations is assumed to be much smaller than the undisturbed water depth, the socalled rigid lid approximation can be adopted.
  • Using a procedure first proposed by Lorentz (1922), see also Zimmerman (1992), the non-linear bottom friction can be linearized in such a way that averaged over one tidal cycle the same amount of energy is dissipated in both formulations.
  • The first term on the right-hand side of Eq. (4) models the sediment pick-up function, and the second term the tendency of sediment to settle due to gravity effects.
  • This seems to be consistent with literature where it is suggested that the transport due to the bed slope terms cannot be neglected (see Parker, 1978; Talmon et al., 1995), even if suspended-load transport dominates.

3. Linear stability analysis

  • For realistic values of the parameters the 2D system of equations, as described in Section 2, allows for a morphodynamic equilibrium solution Weq ¼ ðu; v;rz;C; hÞeq; which is spatially uniform, i.e. they are independent of both the x- and the ycoordinate.
  • Here, ueq ¼ ðueq; 0Þ and u0 ¼ ðu0; v0Þ are the equilibrium and perturbed velocity vector.
  • The ratio of the tidal period and the morphologic timescale is typically of the order of 10 2–10 4: Since Eqs. (8a)–(8d) evolve on the tidal timescale, the bed perturbation h0 in these equations can be considered fixed.
  • The first two terms on the right-hand side of Eq. (13) give the contribution of the divergence of the advective sediment flux Fadv; while the last two terms model the divergences of fluxes due to diffusive processes (Fdiff ) and bedslope effects (Fbed), respectively.
  • The real part of the eigenvalue RðoÞ denotes the growth rate of the perturbation and IðoÞ=k its migration speed.

4. Results

  • In this section results from the local 2D channel model will be described.
  • Default values which are characteristic for the Western Scheldt will be used, see Table 1.
  • In the remainder of this paper, the authors will only consider advective modes, i.e. horizontal dispersion terms in the momentum and concentration equations are neglected ðm ¼.
  • This is justified since the ratio of dispersive to advective fluxes is of the order 10 1–10 3 for the bed form length scales that are considered in this paper.
  • This is also done in the model adopted by Seminara and Tubino (1998).

4.1. Advective instabilities for linear bottom friction

  • 0Þ: Fig. 3 shows the dimensionless growth rate as a function of the dimensionless longitudinal wavenumber k for various values of the lateral number n:.
  • This result is reminiscent from river morphodynamics where this mode is also found to be the most unstable one if bed slope effects are neglected (Callander, 1969).
  • For long waves, sediment transport is mainly driven by the residual velocity perturbation /u0S:.
  • These features will now be explained in more detail.
  • Expression (17) shows that the growth of long-wave perturbations is primarily governed by the residual perturbed velocity /u0S: Fig. 4 shows a typical example of the behaviour of this quantity as the longitudinal wavenumber k varies.

4.2. Bedslope effects

  • The most unstable mode now occurs for finite n: Eigenfunctions with high modenumber n (i.e. fast spatial oscillations in the lateral direction) are damped.
  • For friction values above the neutral curve, bedforms have positive growth rates.
  • The minimum of the neutral curve is referred to as the critical mode for the specified lateral modenumber n and is characterized by the critical wavenumber kcr and friction parameter values rcr:.
  • Since this destabilizing effect has its maximum value for a finite value of k (see Fig. 3), it is to be expected that both rcr and kcr have finite (non-zero) values.

4.3. Non-linear friction and the influence of channel width

  • The authors will extend their model by including non-linear bottom friction, which means that sb in Eq. (2) reads sb ¼ r#rjjujju; ð20Þ where #r ¼ 3pr=ð8UÞ follows from the Lorentz linearization procedure that was mentioned below Eq. (2).
  • The effect of non-linearity on the growth of bedforms can be inferred from Fig. 7 which shows the neutral curves for both linear and nonlinear friction.
  • Also, the most unstable wavenumber shifts towards a higher value, i.e. the critical mode occurs on a shorter longitudinal length scale.
  • The explicit dependence of the non-linear friction parameter #rjjujj on velocity thus yields a decrease of bottom friction above shallow (deep) parts of the channel.
  • So far, the authors have considered a socalled wide channel for which width and tidal excursion length are of the same order of magnitude.

5. Discussion and conclusions

  • The formation of bottom patterns that scale with the tidal excursion length has been studied within a 2D idealized model.
  • In the case that sediment diffusion can be neglected, this instability is mediated by advective processes, in particular through residual flows that arise from tide-topography interactions.
  • Bed slope effects act as a means to prevent the emergence of both longitudinal and lateral smallscale features.
  • All these discrepancies may in principle yield qualitatively different outcome.

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Citations
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Application of a simple and effective method for mangrove afforestation in semiarid regions combining nonlinear models and constructed platforms

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Francisco Flores-de-Santiago1, David Serrano2, Francisco Flores-Verdugo1, Mariana Monroy-Torres1
National Autonomous University of Mexico1, Autonomous University of Sinaloa2
01 Jun 2017-Ecological Engineering
TL;DR: In this article, the authors assess the hydrodynamics of a meandering tidal channel in order to select optimal locations for the construction of platforms, and thus improve the recruitment of white mangrove ( Laguncularia racemosa ) and red mangroves ( Rhizophora mangle ) propagules.

15 citations

Journal ArticleDOI
Prediction of tidal excursion length in estuaries due to the environmental changes

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J Parsa1, A. Etemad Shahidi1
Iran University of Science and Technology1
01 Sep 2010-International Journal of Environmental Science and Technology
TL;DR: In this article, a power function was derived to predict the length of the salinity intrusion in alluvial estuaries based on the geometrical and hydrodynamic properties of the water surface.
Abstract: Tidal excursion is an important parameter that indicates hydraulic and mixing characteristics of estuarine environments. Prediction of the tidal excursion length provides a proper tool for environmental management of estuaries. In this study, the governing equations of the salinity transport were scaled first to recognize the effective dimensionless parameters of tidal excursion length. Then, a laterally averaged two-dimensional numerical model called CE-QUAL-W2 was used as a virtual laboratory to simulate the salinity intrusion length. Existing field data of Limpopo estuary, as a case study, was used for calibration and verification of the model and reasonable agreement was observed between the model results and the field data. Finally, the verified model was used to assess the influences of the governing parameters. The results showed that simple power functions can be used to describe the effects of dimensionless parameters obtained by scaling of the governing equations. As a result, a new formula in form of a power function was derived to predict the tidal excursion length based on the geometric and hydrodynamic characteristics of alluvial estuaries. Comparison of the computed tidal excursion lengths using the derived formula with the observed measurements in several estuaries showed the robustness of the developed formula.

15 citations

Cites background from "The effect of geometry and bottom f..."

  • ...Tidal excursion length also can be used as a length scale in the modeling of sediment transport in estuaries (Schramkowski et al., 2002; Hibma et al., 2003; Kho et al., 2009)....

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Journal ArticleDOI
Three-dimensional semi-idealized model for estuarine turbidity maxima in tidally dominated estuaries

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Mohit Kumar1, Henk M. Schuttelaars1, Pieter C. Roos2
Delft University of Technology1, University of Twente2
01 May 2017-Ocean Modelling
TL;DR: In this paper, a three-dimensional idealized model for the formation of estuarine turbidity maxima in tidally dominated estuaries is developed, which is applied to the Ems estuary using a simplified geometry and bathymetric profiles for the years 1980 and 2005.

14 citations

Journal ArticleDOI
Morphology of bar-built estuaries: empirical relation between planform shape and depth distribution

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Jasper R. F. W. Leuven1, Sanja Selaković1, Maarten G. Kleinhans1
Utrecht University1
11 Sep 2018
TL;DR: In this paper, an empirical relation between along-channel planform geometry, obtained as the outline from imagery, and hypsometry was studied, which characterises the distribution of along channel and cross-channel bed levels.
Abstract: . Fluvial–tidal transitions in estuaries are used as major shipping fairways and are characterised by complex bar and channel patterns with a large biodiversity. Habitat suitability assessment and the study of interactions between morphology and ecology therefore require bathymetric data. While imagery offers data of planform estuary dimensions, only for a few natural estuaries are bathymetries available. Here we study the empirical relation between along-channel planform geometry, obtained as the outline from imagery, and hypsometry, which characterises the distribution of along-channel and cross-channel bed levels. We fitted the original function of Strahler (1952) to bathymetric data along four natural estuaries. Comparison to planform estuary shape shows that hypsometry is concave at narrow sections with large channels, while complex bar morphology results in more convex hypsometry. We found an empirical relation between the hypsometric function shape and the degree to which the estuary width deviates from an ideal convergent estuary, which is calculated from river width and mouth width. This implies that the occurring bed-level distributions depend on inherited Holocene topography and lithology. Our new empirical function predicts hypsometry and along-channel variation in intertidal and subtidal width. A combination with the tidal amplitude allows for an estimate of inundation duration. The validation of the results on available bathymetry shows that predictions of intertidal and subtidal area are accurate within a factor of 2 for estuaries of different size and character. Locations with major human influence deviate from the general trends because dredging, dumping, land reclamation and other engineering measures cause local deviations from the expected bed-level distributions. The bathymetry predictor can be used to characterise and predict estuarine subtidal and intertidal morphology in data-poor environments.

14 citations

Cites background from "The effect of geometry and bottom f..."

  • ...For example, bar theory (Seminara and Tubino, 2001; Schramkowski et al., 2002) could predict occurring bar patterns on top of an (ideal) Earth Surf....

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Journal ArticleDOI
Three-dimensional semi-idealized model for tidal motion in tidal estuaries An application to the Ems estuary

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Mohit Kumar1, Henk M. Schuttelaars1, Pieter C. Roos2, Matthias Möller1
Delft University of Technology1, University of Twente2
01 Jan 2016-Ocean Dynamics
TL;DR: In this paper, a three-dimensional semi-idealized model for tidal motion in a tidal estuary of arbitrary shape and bathymetry is presented, which aims at bridging the gap between idealized and complex models.
Abstract: In this paper, a three-dimensional semi-idealized model for tidal motion in a tidal estuary of arbitrary shape and bathymetry is presented. This model aims at bridging the gap between idealized and complex models. The vertical profiles of the velocities are obtained analytically in terms of the first-order and the second-order partial derivatives of surface elevation, which itself follows from an elliptic partial differential equation. The surface elevation is computed numerically using the finite element method and its partial derivatives are obtained using various methods. The newly developed semi-idealized model allows for a systematic investigation of the influence of geometry and bathymetry on the tidal motion which was not possible in previously developed idealized models. The new model also retains the flexibility and computational efficiency of previous idealized models, essential for sensitivity analysis. As a first step, the accuracy of the semi-idealized model is investigated. To this end, an extensive comparison is made between the model results of the semi-idealized model and two other idealized models: a width-averaged model and a three-dimensional idealized model. Finally, the semi-idealized model is used to understand the influence of local geometrical effects on the tidal motion in the Ems estuary. The model shows that local convergence and meandering effects can have a significant influence on the tidal motion. Finally, the model is applied to the Ems estuary. The model results agree well with observations and results from a complex numerical model.

13 citations

Cites background from "The effect of geometry and bottom f..."

  • ...where s (m s−1) is the stress parameter which follows from the linearization of the quadratic friction law (for details, see Schramkowski et al. (2002) and Zimmerman (1992))....

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  • ...…at the bottom z = −h are prescribed, i.e., Av(uz, vz) = (0, 0), at z = 0, (2c) Av(uz, vz) = s(u, v), at z = −h, (2d) where s (m s−1) is the stress parameter which follows from the linearization of the quadratic friction law (for details, see Schramkowski et al. (2002) and Zimmerman (1992))....

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References
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Book
Principles of sediment transport in rivers, estuaries and coastal seas

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Leo C. van Rijn
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1,962 citations

Additional excerpts

  • ...The evolution equation for C reads (Van Rijn, 1993) Ct þ ðuC mCxÞx þ ðvC mCyÞy ¼ S aðu2 þ v2Þ gC; ð4Þ where m denotes the horizontal coefficient for sediment diffusion and S the difference between erosion and sedimentation at the top of the active layer....

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TL;DR: The physical concepts governing sediment movement in the sea with the minimum of mathematics have been established in this paper, with a focus on the measurement and prediction of sea transportation of sediment, and detailed physical processes within regional sediment circulation patterns.
Abstract: The movement of mud, sand and gravel on the continental shelf, in the nearshore zone, on beaches and in estuaries can be significant in economic and environmental terms. From ease of navigation, to liability to flooding, from sewage and waste disposal to fish populations changes in the deposition and erosion of sedimentary material can have an effect on man's activities in the shoreline zone. Coastal and Estuarine Sediment Dynamics discusses such movements using the different viewpoints of the marine geologists, the oceanographer and the engineer, and integrates them into an essentially multidisciplinary treatment. Quantified descriptions of the physical processes causing sedimentary movement and response are emphasised in the context of natural systems. Among the features included in this book are: Establishment of physical concepts governing sediment movement in the sea with the minimum of mathematics; Essential background material and up-to- date research results; Information on the measurement and prediction of sea transportation of sediment; Detailed physical processes within regional sediment circulation patterns.

981 citations

Additional excerpts

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TL;DR: In this paper, the effects of space discretization on wave propagation are investigated and a detailed treatment of boundary conditions is given. But the results are limited to three-dimensional shallow-water flows.
Abstract: Preface. 1. Shallow-water flows. 2. Equations. 3. Some properties. 4. Behaviour of solutions. 5. Boundary conditions. 6. Discretization in space. 7. Effect of space discretization on wave propagation. 8. Time integration methods. 9. Effects of time discretization on wave propagation. 10. Numerical treatment of boundary conditions. 11. Three-dimensional shallow-water flow. List of notations. References. Index.

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"The effect of geometry and bottom f..." refers background in this paper

  • ...The water motion is described by the depthaveraged shallow water equations (see Vreugdenhil, 1994)....

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Self-formed straight rivers with equilibrium banks and mobile bed. Part 1. The sand-silt river

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Gary Parker1
University of Alberta1
14 Nov 1978-Journal of Fluid Mechanics
TL;DR: In this paper, the authors formulated a fluid flow model with a series of approximate but reasonable assumptions for straight channels with non-cohesive sand and silt banks and showed that the model can be applied to a more general treatment of natural rivers, which would include various complicating factors such as meandering, sediment sorting and seepage.
Abstract: Rivers and canals with perimeters composed of non-cohesive sand and silt have self-formed active beds and banks. They thus provide a most interesting fluid flow problem, for which one must determine the container as well as the flow. If bed load alone occurs across the perimeter of a wide channel, gravity will pull particles down the lateral slope of the banks; bank erosion is accomplished and the channel widens. In order to maintain equilibrium, this export of material from the banks must be countered by an import of sediment from the channel centre.The mechanism postulated for this import is lateral diffusion of suspended sediment, which overloads the flow near the banks and causes deposition. The model is formulated analytically with the aid of a series of approximate but reasonable assumptions. Singular perturbation techniques are used to define the channel geometry and obtain rational regime relations for straight channels. A comparison with data lends credence to the model.It is hoped that a first step has been made towards a more general treatment, which would include various complicating factors that are important features of natural rivers but are not essential to the maintenance of channel width. Among these factors are meandering, sediment sorting and seepage.

288 citations

"The effect of geometry and bottom f..." refers result in this paper

  • ...This seems to be consistent with literature where it is suggested that the transport due to the bed slope terms cannot be neglected (see Parker, 1978; Talmon et al., 1995), even if suspended-load transport dominates....

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Laboratory measurements of the direction of sediment transport on transverse alluvial-bed slopes

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A.M. Talmon, N. Struiksma, M.C.L.M. Van Mierlo
01 Jul 1995-Journal of Hydraulic Research
TL;DR: In this article, the effect of a sloping bed on the direction of sediment transport is determined by conducting bed-levelling experiments, and a distinction is made between laboratory conditions and natural rivers.
Abstract: Laboratory experiments have been conducted to provide data for modelling the direction of sediment transport on a transverse sloping alluvial bed. Conditions with prevailing bed-load transport, and conditions in which a significant part of the bed material is transported as suspended-load are studied. The effect of a sloping bed on the direction of sediment transport is determined by conducting bed-levelling experiments. Comparison of the results with data of curved flume experiments and experience gained with numerical computation of the bed topography in natural rivers yields the conclusion that, at least for bed-load transport, a distinction should be made between laboratory conditions and natural rivers. For conditions with suspended sediment transport the transverse slope effect can not be modelled identical as for bed-load transport.

262 citations

"The effect of geometry and bottom f..." refers result in this paper

  • ...This seems to be consistent with literature where it is suggested that the transport due to the bed slope terms cannot be neglected (see Parker, 1978; Talmon et al., 1995), even if suspended-load transport dominates....

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Frequently Asked Questions (1)
Q1. What are the contributions mentioned in the paper "The effect of geometry and bottom friction on local bed forms in a tidal embayment" ?

In the case that the width is much smaller than the tidal excursion length and non-linear bottom friction is used, there is good qualitative agreement with results from 3D models reported in literature which were applied to the same parameter regime.