Effect of vegetation cover and sediment type on 3D subsurface structure and shear strength in saltmarshes

Chirol, Clémentine; Spencer, Kate L.; Carr, Simon; Möller, Iris; Evans, Ben; Lynch, Jason; Brooks, Helen; Royse, Katherine

doi:10.1002/esp.5174

Cited by 16 publications

(10 citation statements)

References 63 publications

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“…4d) suggesting s ∼10. We believe that this effect is mainly associated to the presence of the in situ root structure of the living vegetation cover present in the upper 0.20-0.25 m. This is in agreement with recent reports on the beneficial effects exerted by halophytes roots and rhizomes on marsh shear and compressibility strength 18,57 .…”

Section: Discussionsupporting

confidence: 92%

In-situ loading experiments reveal how the subsurface affects coastal marsh survival

Zoccarato

Minderhoud

Zorzan

et al. 2022

Commun Earth Environ

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Over the past decades coastal marshes around the world have declined dramatically. Their deterioration is controlled by scarcity of sediments, erosion and accelerated rise of relative sea-level. The feedbacks between these processes control marsh evolution and determine their long-term survivability. Aggradation of a marsh to keep pace with relative sea-level rise mainly depends on the interplay between sedimentation and autocompaction, but their interactions are severely understudied. Here we present an in-situ loading experiment applied in the Venice Lagoon, Italy, to assess long-term autocompaction, with subsurface displacements and pressure monitored during loading cycles, up to ∼40 kN applied on a ∼4 m2 surface. Two identical experiments carried out in inorganic and organic soil-dominated marshes provided unique insights on the spatio-temporal subsurface dynamics. The large differences in behavior and maximum compaction (6 vs 32 mm) underscore the crucial role of autocompaction and soil heterogeneity when predicting the fate of coastal marshes worldwide.

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Section: Discussionsupporting

confidence: 92%

In-situ loading experiments reveal how the subsurface affects coastal marsh survival

Zoccarato

Minderhoud

Zorzan

et al. 2022

Commun Earth Environ

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“…The latter species grows faster initially, but its biomass declines over the winter period, and hence explicit seasonality is required to model this species. For inclusion of different species and to improve single‐species simulations, belowground feedback between morphology and vegetation, that is, spatio‐temporal differences in substrate strength (Chirol et al., 2021), is required. This can be simulated by implementing a spatio‐temporal varying critical bed shear stresses.…”

Section: Discussionmentioning

confidence: 99%

Modeling Decadal Salt Marsh Development: Variability of the Salt Marsh Edge Under Influence of Waves and Sediment Availability

Willemsen

Smits

Borsje

et al. 2022

Water Resources Research

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“…Cohesion in sandy loam agricultural soils also tends to be higher, with Mouazen (2002) considerable increases in cohesion due to the presence of roots. However, the salt marsh samples used here contained not only roots but likely also macropores, which are known to be related to a lower shear strength at these sites (Chirol et al, 2021) and the interpretation of results is necessarily more complicated.…”

Section: Cohesional Strength and Angle Of Internal Frictionmentioning

confidence: 99%

How strong are salt marshes? Geotechnical properties of coastal wetland soils

Brooks

Moeller

Spencer

et al. 2022

Earth Surf Processes Landf

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Salt marshes are globally distributed, vegetated intertidal wetlands and marsh edge erosion is common on many shores. To understand how and why marsh edge erosion occurs, the response of salt marsh substrates to applied shear and vertical stress must first be quantified. This response is likely influenced by marsh substrate biological, geochemical and sedimentological composition. However, currently there is little systematic research into the between‐marsh variability in these properties and how they affect both marsh edge erosion processes and the ability of a marsh to maintain its position vertically within the tidal frame. This paper compares two marshes of contrasting sedimentology at Tillingham marsh, East England and Warton marsh, Northwest England. Soil shear strength and compressibility are determined by applying geotechnical methods to determine marsh resistance to shear and vertical effective stresses. This research was able to isolate the influence of roots on substrate shear strength in a three‐dimensional sample. In response to vertical effective stress, both the expected displacement magnitude and the vertical recovery potential of a marsh substrate are affected by past stress conditions on the marsh, particularly those resulting from desiccation. The substrate response to vertical effective stress also influences substrate shear strength through the effect of consolidation on the void ratio (or bulk density). We present evidence for the connection between marsh composition and substrate behaviour under applied stress. The results shed light on potential determinants of marsh resistance to edge erosion, which is ultimately essential for the informed implementation of both nature‐based coastal flood defences and coastal restoration schemes.

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Effect of vegetation cover and sediment type on 3D subsurface structure and shear strength in saltmarshes

Cited by 16 publications

References 63 publications

In-situ loading experiments reveal how the subsurface affects coastal marsh survival

In-situ loading experiments reveal how the subsurface affects coastal marsh survival

Modeling Decadal Salt Marsh Development: Variability of the Salt Marsh Edge Under Influence of Waves and Sediment Availability

How strong are salt marshes? Geotechnical properties of coastal wetland soils

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