Sediment dynamic responses of coastal salt marsh to wind waves and swells in a semi-open tidal flat

Coastal salt marshes provide effective protection to the coastal environments they front against coastal erosion by reducing the incoming wave energy. Understanding sediment dynamic processes in coastal salt marshes environments is of crucial importance for coastal defense. The objective of this stu...

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Bibliographic Details
Published in:The Science of the total environment 2024-12, Vol.954, p.176562, Article 176562
Main Authors: Chen, Shaoxin, Gu, Weifang, Shi, Benwei, Chen, Yining, Chatzipavlis, Antonis, Ding, Jiawei, Zhang, Wenxiang, Chen, Qi, Wang, Ya Ping
Format: Article
Language:English
Subjects:
Salt marsh
Sediment transport
Spartina alterniflora
Tidal flat
Wave attenuation
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Summary:Coastal salt marshes provide effective protection to the coastal environments they front against coastal erosion by reducing the incoming wave energy. Understanding sediment dynamic processes in coastal salt marshes environments is of crucial importance for coastal defense. The objective of this study is to assess the impact of Spartina alterniflora (S. alterniflora) marshes on wave attenuation, sediment transport, and morphodynamics through extensive field records on the Cixi tidal flat in Hangzhou Bay. Results demonstrate that wave attenuation by S. alterniflora marshes increases proportionally with the intensification of wind waves at a consistent water depth or significant wave height. Moreover, wave attenuation in the context of wind waves surpasses that of swells. On average, the wave attenuation provided by S. alterniflora marshes during both wind waves and swells is more than six times greater than that offered by the adjacent mudflat. Additionally, net sediment fluxes within S. alterniflora marshes decrease by 37 % in the presence of swells and 84 % with wind waves, in comparison to the mudflat. The influence of S. alterniflora marshes on tidal flat accretion is more pronounced with wind waves than swells. Notably, observed from summer to winter, the surface accretion of tidal flats is highest (∼26 cm) at the edge of S. alterniflora marshes. This study contributes valuable insights into the complex interactions between salt marshes and hydrodynamic forces, essential for informing coastal management strategies. [Display omitted] •Wave attenuation by salt marshes increases with the intensification of wind waves.•Wave attenuation in the context of wind waves surpasses that of swells.•Surface accretion of tidal flats is highest at the edge of salt marshes.•Net sediment fluxes within salt marshes were lower in the presence of wind waves than swells.
ISSN:0048-9697
1879-1026
1879-1026
DOI:10.1016/j.scitotenv.2024.176562