Ecohydraulics of Surrogate Salt Marshes for Coastal Protection: Wave–Vegetation Interaction and Related Hydrodynamics on Vegetated Foreshores at Sea Dikes

Keimer, Kara; Schürenkamp, David; Miescke, Fenia; Kosmalla, Viktoria; Lojek, Oliver; Goseberg, Nils

doi:10.1061/(asce)ww.1943-5460.0000667

Cited by 15 publications

(16 citation statements)

References 56 publications

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“…12 and 18), a minimum foreshore slope of 1/1000 (or 0.1 %) is considered here. This is in line with the common approach where slopes milder than or equal to 0.1 % are treated equally as (nearly) flat (Keimer et al, 2021;Steendam et al, 2004). Note that the calculated foreshore slopes ranged from −0.04 % to 4 % with an average of 0.14 %, where a negative slope indicates a slight downward slope towards the dike toe.…”

Section: Dike-foreshore Characteristicssupporting

confidence: 84%

The influence of infragravity waves on the safety of coastal defences: a case study of the Dutch Wadden Sea

Lashley

Jonkman

Meer

et al. 2022

Nat. Hazards Earth Syst. Sci.

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Abstract. Many coastlines around the world are protected by dikes with shallow foreshores (e.g. salt marshes and mudflats) that attenuate storm waves and are expected to reduce the likelihood and volume of waves overtopping the dikes behind them. However, most of the studies to date that assessed their effectiveness have excluded the influence of infragravity (IG) waves, which often dominate in shallow water. Here, we propose a modular and adaptable framework to estimate the probability of coastal dike failure by overtopping waves (Pf). The influence of IG waves on overtopping is included using an empirical approach, which is first validated against observations made during two recent storms (2015 and 2017). The framework is then applied to compare the Pf values of the dikes along the Dutch Wadden Sea coast with and without the influence of IG waves. Findings show that including IG waves results in 1.1 to 1.6 times higher Pf values, suggesting that safety is overestimated when they are neglected. This increase is attributed to the influence of the IG waves on the design wave period and, to a lesser extent, the wave height at the dike toe. The spatial variation in this effect, observed for the case considered, highlights its dependence on local conditions – with IG waves showing greater influence at locations with larger offshore waves, such as those behind tidal inlets, and shallower water depths. Finally, the change in Pf due to the IG waves varied significantly depending on the empirical wave overtopping model selected, emphasizing the importance of tools developed specifically for shallow foreshore environments.

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Section: Dike-foreshore Characteristicssupporting

confidence: 84%

The influence of infragravity waves on the safety of coastal defences: a case study of the Dutch Wadden Sea

Lashley

Jonkman

Meer

et al. 2022

Nat. Hazards Earth Syst. Sci.

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“…Furthermore, the results can be implemented into modeling approaches, including the coastal protection potential of above-ground biomass of salt marsh vegetation. Physical surrogates (see, for example, Augustin et al, 2009;van Veelen et al, 2020;Keimer et al, 2021;Keimer et al, 2022) can be adjusted to incorporate the aspect of seasonality for different storm scenarios. Furthermore, numerical simulations can be extended to include the variance in vegetation properties (see, for example, van Loon-Steensma et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

“…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%

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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“…simply compensate for the anticipated loss of biodiversity [7]. A promising approach to promote coastal resilience are nature-based solutions (NbS) that offer or even exploit services provided by ecosystems [8,9], e.g., wave attenuation [10,11], accretion of sediments or reduction of erosion naturally provisioned or supported by coral reefs, salt marshes, seagrass meadows or coastal dunes [12][13][14][15][16]. Further studies and experiences of NbS are provided and discussed, e.g., by Scheres et al [17] on alternative plant coverage and its root systems stabilizing sea dikes or by Staudt et al [18] on the ecological dimensions of beach and foreshore nourishments with marine aggregates, such as sand and gravel.…”

Section: Introductionmentioning

confidence: 99%

Design and Insights Gained in a Real-World Laboratory for the Implementation of New Coastal Protection Strategies

Kempa¹,

Karrasch²,

Schlurmann³

et al. 2023

Preprint

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Novel strategies in coastal protection are needed to cope with climate change-induced sea level rise. They aim at the sustainable development of coastal areas in light of an intensification and land use changes. A promising approach is the design of nature-based solutions (NbS), complementing the safety levels of technical infrastructures. However, NbS lack a widespread and large-scale implementation. To address this deficit, co-design concepts are needed that combine experiences from science and practice. This work presents and discusses the approach of a coast-specific real-world laboratory (RwL) addressing the inclusive design of ecosystem-based coastal protection. Strategies of RwLs are applied for the first time in a coastal context along the North Sea coastline in Germany. We found the concept of RwLs suitable for coastal transdisciplinary research, although adaptions in the spatial reference level or flexibility in location and time of experimentation are necessary. A profound actor analysis is indispensable to specify participatory processes and interaction levels. A criteria-based cooperative selection of RwL sites helps to reveal and solve conflicting interests to achieve trust between science and practice. Addressing site-specific characteristics and practitioners’ needs, our coastal RwL provides a mutual learning space to develop and test NbS to complement technical coastal protection.

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Ecohydraulics of Surrogate Salt Marshes for Coastal Protection: Wave–Vegetation Interaction and Related Hydrodynamics on Vegetated Foreshores at Sea Dikes

Cited by 15 publications

References 56 publications

The influence of infragravity waves on the safety of coastal defences: a case study of the Dutch Wadden Sea

The influence of infragravity waves on the safety of coastal defences: a case study of the Dutch Wadden Sea

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

Design and Insights Gained in a Real-World Laboratory for the Implementation of New Coastal Protection Strategies

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