Modelling the contribution of wind waves to Cap Ferret's updrift erosion

Wind waves breaking at an angle with the shoreline force the drifting of littoral sediments, which is known for contributing to the formation and growth of barrier spits. Intriguingly, increased rates of longshore wave power have also been associated with the erosion of some barrier spits on the upd...

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Bibliographic Details
Published in:Coastal Engineering
Main Authors: NAHON, Alphonse, IDIER, Deborah, BERTIN, Xavier, GUERIN, Thomas, MARIEU, Vincent, SENECHAL, Nadia, MUGICA, Julie
Format: Article in Journal/Newspaper
Language:English
Published: 2022
Subjects:
Sandspit
Tidal inlet
Sediment transport
Wave power
NAO
SCHISM
Sciences de l'environnement
The Spit
North Atlantic
North Atlantic oscillation
Online Access:https://oskar-bordeaux.fr/handle/20.500.12278/184690
https://hdl.handle.net/20.500.12278/184690
https://doi.org/10.1016/j.coastaleng.2021.104063
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Summary:Wind waves breaking at an angle with the shoreline force the drifting of littoral sediments, which is known for contributing to the formation and growth of barrier spits. Intriguingly, increased rates of longshore wave power have also been associated with the erosion of some barrier spits on the updrift margin of tidal inlets. Therefore, a numerical experiment was designed and is presented here, which investigates the possible links between the longshore wave power and the shortening of these elongated coastal barriers. Based on a process-based model, the experiment provides new insights into the forces at play in the redistribution of sediments between a sandspit and its adjacent inlet, respectively the Cap Ferret and the Bay of Arcachon's tidal inlet, in SW France. More particularly, model scenarios were defined that show how combined waves and tide create gradients of residual sediment transport responsible for a sediment deficit at the spit – inlet boundary. The deficit was also found to deepen with increasing longshore wave energy, as if the transfer of sediment from the spit to inlet shoals was accelerated. This physically explains the previously observed retreat of the spit's distal end during periods dominated by the positive phase of North Atlantic Oscillation (NAO) in winter. Indeed, according to model results, higher and/or more oblique waves associated with the positive phase of the NAO are expected to increase the transfer and storage of the drifting sediments to and by the inlet shoals, and this at the expense of the spit. While these conclusions remain valid, we noticed that the sensitivity of model results to the bottom friction enhanced the importance of accurately representing the spatio-temporal distribution of bed roughness when investigating the morphodynamic interactions between real-world tidal inlets and their margins.

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