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Flow velocity profiles in the Lower Scheldt estuary
Winterwerp, J.C.; Wang, Z.B.; van der Kaaij, T.; Verelst, K.; Bijlsma, A.; Meersschaut, Y.; Sas, M. (2006). Flow velocity profiles in the Lower Scheldt estuary. Ocean Dynamics 56(3-4): 284-294. https://dx.doi.org/10.1007/s10236-006-0063-4
In: Ocean Dynamics. Springer-Verlag: Berlin; Heidelberg; New York. ISSN 1616-7341; e-ISSN 1616-7228
Peer reviewed article  

Available in  Authors 
  • VLIZ: Open Marine Archive 280369 [ download pdf ]
  • Waterbouwkundig Laboratorium: Open Repository 126001 [ OWA ]

Keywords
    Bends
    Estuarine circulation
    Estuarine environment
    Profiles > Vertical profiles > Velocity profiles
    River currents
    River flow
    River morphology
    Belgium, Zeeschelde, Antwerp [Marine Regions]
    Brackish water
Author keywords
    river bends; secondary currents; gravitational circulation; estuarine morphology

Authors  Top 
  • Winterwerp, J.C.
  • Wang, Z.B.
  • van der Kaaij, T.
  • Verelst, K.
  • Bijlsma, A.
  • Meersschaut, Y.
  • Sas, M.

Abstract
    Recent acoustic Doppler current profiler (ADCP)-measurements in the Scheldt estuary near Antwerp, Belgium, revealed anomalous, i.e. anti-clockwise circulations in a left bend during the major part of the flood period; these circulations were established shortly after the turn of the tide. During ebb, anti-clockwise circulations persisted, as predicted by classical theory. These data were analysed with a 3D and a 1DV-model. The 3D simulations reveal that the anomalous circulations are found when salinity is included in the computations—without salinity “normal” circulations were found. From analytical and 1DV simulations, it is concluded that a longitudinal salinity gradient may induce a near-bed maximum in flow velocity reversing the direction of the secondary currents. The 1DV-model was then used to assess the contribution of various processes one by one. It was found that because of a reduction in vertical mixing, the vertical velocity profile is not at equilibrium during the first phase of accelerating tide, further enhancing the effects of . A small vertical salinity gradient appeared to have a very large effect as the crosscurrents of the secondary circulations induced by became an order of larger magnitude. However, at the site under consideration, the effects of transverse salinity gradients, generated by differential advection in the river bend, were dominant: adverse directions of the secondary circulations were found even when the vertical velocity profile became more regular with a more or less logarithmic shape, i.e. when the effects of and did not play a dominant role anymore. It is argued that data on the secondary velocity structure, which can be measured easily owing to today’s developments in ADCP equipment, may serve as an indicator for the accuracy at which the salinity field is computed with 3D numerical models. Moreover, the large effect of the salinity structure on the velocity field must have a large impact on the morphological development of estuaries, which should therefore be accounted for in morphological modelling studies.

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