The water circulation near the Danube Delta and the Romanian coast modelled with finite elements

A numerical model, based on a finite element discretisation technique, was used to study water circulation in the Black Sea׳s north-western shelf, particularly near the Danube Delta and the Romanian coast. The numerical grid covers the entire Black Sea and the model resolution is gradually increased...

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Bibliographic Details
Published in:Continental shelf research 2014-04, Vol.78, p.62-74
Main Authors: Bajo, Marco, Ferrarin, Christian, Dinu, Irina, Umgiesser, Georg, Stanica, Adrian
Format: Article
Language:English
Subjects:
Black sea
Coastal
Coastal current
Coastal environments
Danube Delta
Deltas
Finite element model
Hydrodynamics
Mathematical models
River plume
Salinity
Shelves
Water circulation
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Summary:A numerical model, based on a finite element discretisation technique, was used to study water circulation in the Black Sea׳s north-western shelf, particularly near the Danube Delta and the Romanian coast. The numerical grid covers the entire Black Sea and the model resolution is gradually increased versus the Romanian coast to resolve both mesoscale and microscale hydrodynamic features. Sea level, water temperature and CTD profiles, collected in the north-western shelf, were used to validate the model. The seasonal and daily coastal hydrodynamics, in 2009, were studied using 3-D water current and salinity fields. Moreover, different numerical tracers were released on the Danube׳s arms to characterise the Danube׳s plume extension. Results show that near the Danube Delta the strong salinity stratification confines most of the wind momentum input to the surface water layer, while the subsurface current is mostly influenced by the open sea circulation. In the southern Romanian coast, the vertical salinity gradient is weaker and the action of the wind can reach deeper layers. The numerical tracers show a net predominance of the Kilia branch and how coastal anticyclonic eddies can trap the river freshwater, carrying it away from the coast. This happens especially in spring, when the Danube׳s discharge is high and a large eddy is active in front of the Kilia branch. •We model the Black Sea, with a focus on the shelf area near the Danube Delta.•The finite element model allows a high resolution in the study area.•The salinity stratification and the wind are of primary importance in this zone.•Anticyclonic meanders near the delta carry riverine water offshore.
ISSN:0278-4343
1873-6955
DOI:10.1016/j.csr.2014.02.006