Assessment of in-situ tidal marsh erodibility under high flow velocities

M. van den Berg*, S. J. H. Rikkert, S. G. J. Aarninkhof, R. J. Labeur

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

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Abstract

Coastal flood risk is expected to increase due to climate change and population
growth. Much of our coastlines is protected by “grey” infrastructure such as a dike.
Dike maintenance and strengthening requires ever increasing capital and space,
putting their economic viability in question. To combat this trend, more
sustainable alternatives are explored, also known as Nature based Solutions. A
promising option has shown to be tidal marshes. Tidal marshes are coastal
wetlands with high ecological and economic value. Also, they protect dikes
through wave attenuation and in case of a dike breach reduce its development.
However, the effectiveness of a tidal marsh on reducing dike breach development
rates highly depends on the stability of the tidal marsh itself. Not much is known
about the stability of a tidal marsh under dike breach conditions, which are
accompanied with flow velocities that can reach 4–5ms−1. In this study we tested
the vegetation response and erodibility of a mature tidal marsh, in-situ, under high
flow velocities ( > 0.5ms−1). Our results confirm that tidal marshes similar to the
one tested in this study are highly erosion resistant with low erodibility. More
research is necessary to confirm this for tidal marshes with different soil and
vegetation properties. For tidal marshes similar to what is tested thus far, erosion
under dike breach conditions is negligible and other erosion mechanisms such as
headcut erosion probably dominate the erosion process.
Original languageEnglish
Article number1385610
Number of pages18
JournalFrontiers in Environmental Science
Volume12
DOIs
Publication statusPublished - 2024

Keywords

  • tidal marsh
  • erodibility
  • flow
  • in-situ
  • dike breach
  • flood risk
  • coastal adaptation

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