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A finite-element, multi-scale model of the Scheldt tributaries, river, estuary and ROFI
de Brye, B.; de Brauwere, A.; Gourgue, O.; Kärnä, T.; Lambrechts, J.; Comblen, R.; Deleersnijder, E. (2010). A finite-element, multi-scale model of the Scheldt tributaries, river, estuary and ROFI. Coast. Eng. 57(9): 850-863. dx.doi.org/10.1016/j.coastaleng.2010.04.001
In: Coastal Engineering: An International Journal for Coastal, Harbour and Offshore Engineers. Elsevier: Amsterdam; Lausanne; New York; Oxford; Shannon; Tokyo. ISSN 0378-3839; e-ISSN 1872-7379
Peer reviewed article  

Available in  Authors 
  • VLIZ: Non-open access 219549 [ request ]
  • Waterbouwkundig Laboratorium: Non-open access 157651 [ request ]

Keywords
    Finite elements
    Models
    Motion > Tidal motion > Tides
    Physics > Mechanics > Fluid mechanics > Hydrodynamics
    Properties > Chemical properties > Salinity
Author keywords
    Finite-element; Model; Scheldt Estuary; Tide; Hydrodynamics; Multi-scale; Salinity; Lagrangian residual velocity

Authors  Top 
  • de Brye, B.
  • de Brauwere, A.
  • Gourgue, O.
  • Kärnä, T.
  • Lambrechts, J.
  • Comblen, R.
  • Deleersnijder, E.

Abstract
    We report on the development and validation of a coupled two- and one-dimensional finite-element model for the Scheldt tributaries, River, Estuary and region of fresh water influence (ROFI). The hydrodynamic equations are solved on a single, unstructured, multi-scale mesh stretching from the shelf break to the Scheldt tributaries. The tide is forced on the shelf break and propagates upstream in the riverine network. Upstream boundaries lie on sluices or outside of the region of tidal dominance where daily averaged discharges are imposed. Two-dimensional, depthaveraged shallow water equations are solved by means of the discontinuous Galerkin (DG) method over the marine and estuarine parts of the computational domain. In the rivers, however, one-dimensional equations are dealt with using the DG method with the addition of a technique to cope with confluence points. Model parameters are carefully calibrated, leading to the simulation of wind- and tide-forced flows that are in excellent agreement with available data. The diffusivity in the transport equation is calibrated using timeseries of salinity at various locations in the estuary. Finally, the Lagrangian residual transport in the estuary an the adjacent coastal zone is investigated. This work is a major step towards an integrated model for studying the dynamics of waterborne contaminants and the water renewal timescales in the Scheldt land-sea continuum.

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