Stability of a Tidal Marsh Under Very High Flow Velocities and Implications for Nature-Based Flood Defense

Schoutens, Ken; Stoorvogel, Marte; Berg, Mario van den; Hoven, Kim van den; Bouma, Tjeerd J.; Aarninkhof, S.G.J.; Herman, Peter M. J.; Loon-Steensma, J.M. van; Meire, Patrick; Schoelynck, Jonas; Peeters, P.; Temmerman, Stijn

doi:10.3389/fmars.2022.920480

Cited by 10 publications

(15 citation statements)

References 112 publications

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“…It should be further investigated if the different phenological states have an impact on biogeomorphology. Previous studies have already shown that below-ground effects of rootsoil interaction are important for energy reduction due to shoaling and erosion reduction (Alam et al, 2018;Redelstein et al, 2018;Kosmalla et al, 2022;Schoutens et al, 2022). This study therefore proposes to include above-ground plant state for future investigations on above as well as below-ground biomass.…”

Section: Discussionmentioning

confidence: 95%

“…Ecosystem-based coastal defenses (Schoonees et al, 2019) provide multiple ecosystem services (European Commission and Directorate-General for Environment, 2014;Haines-Young and Potschin, 2018), enhancing their environmental value while bolstering natural resilience (Bouma et al, 2014;Doswald et al, 2014). Salt marshes, taking reference to various globally distributed sites (Mcowen et al, 2017), have been studied in laboratories and in the field to evaluate multiple ecosystem services, like the absorption of hydrodynamic energy (Ghisalberti and Nepf, 2006;Augustin et al, 2009;Ysebaert et al, 2011;Koftis et al, 2013;Anderson and Smith, 2014;Möller et al, 2014;Carus et al, 2016;Vuik et al, 2016;Rupprecht et al, 2017;Lou et al, 2018;Garzon et al, 2019;van Veelen et al, 2020;Willemsen et al, 2020;Keimer et al, 2021;Zhang et al, 2022), sediment accretion (Christiansen et al, 2000;Cahoon et al, 2006;Andersen et al, 2011;Baaij et al, 2021;Cahoon et al, 2021;Proenca et al, 2021), soil stabilization (Ford et al, 2016;Kosmalla et al, 2022;Schoutens et al, 2022) and geomorphological changes Chen et al, 2020;Cao et al, 2021;Ladd et al, 2021).The above-mentioned effects depend on vegetation species, traits of the above-and below-ground biomass and hydrodynamic conditions (Schoutens et al, 2020). Integrating and upscaling the presence of salt marshes into coastal protection plans, thus, adds multiple protection funct...…”

Section: Introductionmentioning

confidence: 99%

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Proposing a novel classification of growth periods based on biomechanical properties and seasonal changes of Spartina anglica

Keimer

Kosmalla²,

Prüter³

et al. 2023

Front. Mar. Sci.

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Salt marshes are a valuable ecosystem with coastal protection potential, for example by absorbing hydrodynamic energy, increasing sedimentation and stabilizing the soil. This study investigated biomechanical properties of Spartina anglica to improve future models of wave-vegetation interaction. To fully understand the correlations between hydro- and biomechanics, the biomechanical vegetation properties from December 2021 to July 2022 are investigated with specimens collected from the field monthly. 551 specimens were used to determine the vegetation properties during storm surge season with high hydrodynamic forces. Additional geometrical properties were determined for 1265 specimens. Three-point bending tests measured the stiffness S (N/mm) and maximum forces Fmax (N). Different phenological states were observed over time and separated for analysis. These states provide a novel classification of growth periods for evaluating the coastal protection potential of Spartina anglica. Especially during storm season, most specimen were identified as broken shoots with a mean stiffness of 1.92N/mm (using 304 samples) compared to the bottom part of flowering shoots in December and January with a mean stiffness of 2.98N/mm (using 61 samples). The classification of plant properties recognizing phenological differences, based on plant state and seasonality, can be used to explain and reduce variability of biomechanical properties obtained during field campaigns. Additionally, this study shows that March to April is recommended for future investigations focusing on shoot properties during storm surge season, which is the important season for coastal engineers considering vegetation state.

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Section: Discussionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Proposing a novel classification of growth periods based on biomechanical properties and seasonal changes of Spartina anglica

Keimer

Kosmalla²,

Prüter³

et al. 2023

Front. Mar. Sci.

View full text Add to dashboard Cite

show abstract

“…In relation to managed realignment there is a practical advantage. Sod removal lowers the elevation of high elevated foreshores that would otherwise limit water flow into the realignment site (van den Berg et al, in prep; Schoutens et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

Greening the dike revetment with historic sod transplantation technique in a living lab

van den Hoven,

Grashof‐Bokdam,

Slim

et al. 2024

J Flood Risk Management

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Coastal flood managers seek to anticipate future flood risk and as a result consider the adaptation of flood defences. Instead of crest heightening, dikes can be adapted to include hydrodynamic reducing vegetated foreshores to form a nature‐based hybrid flood defence, for instance; at managed realignments. In this study we investigated the potential of vegetated revetments as a natural continuous connection between the realigned dike and restored foreshore. We applied the historic grass sod transplantation technique with the aim to improve our understanding of the strength of a transplanted sod revetment. In Living Lab Hedwige‐Prosperpolder, dikes were available for in‐situ experiments during managed realignment preparations. We transplanted grass sods and studied erosion resistance after one growth season. Our results show transplanted sod vegetation continued to grow and started to attach to the clay layer. While erosion occurred under extreme wave impact and overflow, the sod pulling method revealed individual sod strength. In conclusion, sod transplantation is a good technique to source local material for green realigned dike revetments. A vegetated dike revetment can hereby create a natural continuous connection between the realigned dike and foreshore, which benefits flood protection as well as flora and fauna.

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“…The flow flumes were constructed from the dike crest, along the outer slope to the dike toe and on the tidal marsh. Schoutens et al (2022) measured soil and vegetation characteristics at the tidal marsh 50 m North of the experimental site at end of January 2021 (Figure 1D). In this study we adopt their results, based on the assumption that in the proximity of this location, soil and vegetation conditions are also representative of our site.…”

Section: Experimental Sitementioning

confidence: 99%

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

van den Berg,

Rikkert,

Aarninkhof

et al. 2024

Front. Environ. Sci.

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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 4–5 m s−1. In this study we tested the vegetation response and erodibility of a mature tidal marsh, in-situ, under high flow velocities (>0.5 m s−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.

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Stability of a Tidal Marsh Under Very High Flow Velocities and Implications for Nature-Based Flood Defense

Cited by 10 publications

References 112 publications

Proposing a novel classification of growth periods based on biomechanical properties and seasonal changes of Spartina anglica

Proposing a novel classification of growth periods based on biomechanical properties and seasonal changes of Spartina anglica

Greening the dike revetment with historic sod transplantation technique in a living lab

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

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