Numerical study of sediment transport on a tidal flat with a patch of vegetation

Ma, Gangfeng; Han, Yu; Niroomandi, Arash; Lou, Sha

doi:10.1007/s10236-014-0804-8

Cited by 17 publications

(9 citation statements)

References 34 publications

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“…They are generally associated with extensive areas covered with Schoenoplectus californicus (totora) and Spartina densiflora (commonly known as espartina), which are assigned a major ecological value, because of their fundamental role as environmental engineers. These macrophyte species, model and stabilize the wetland shores against external hydraulic stress factors (Valdovinos et al, 2010), and capture suspended material in their canopy structures (Madsen et al, 2001;Bouma et al, 2005;Leonard & Croft, 2006;Anthony, 2008;Ma et al, 2014). Therefore, the occurrence and (Fig.…”

Section: Discussionmentioning

confidence: 99%

Tidal flats of recent origin: distribution and sedimentological characterization in the estuarine Cruces River wetland, Chile

Manzano-Castillo

Jaramillo-Lopetegui²,

Pino³

2020

Lat. Am. J. Aquat. Res.

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The sedimentary intertidal surfaces (tidal flats from here on) in coastal wetlands are globally recognized by their biological diversity and available ecosystem services. In Chile, these environments are mainly distributed between 30 and 41°S and associated with micro-tidal estuaries. The estuarine Cruces River Wetland (CRW) was formed by tectonic subsidence caused by the giant 9.5 MW Valdivia earthquake in May 1960. The CRW is characterized by relatively uniform water quality conditions and tidal ranges and a significant increase of discharge and elevation of the water table concurrent with intense winter precipitations. The present study focuses on the presence and distribution of tidal flats in the CRW. It evaluates the spatio-temporal variability (April vs. December 2016) of texture and geochemical parameters (pH and ORP (oxidation/reduction potential, ORP)) of surface sediments in six particular tidal flats located along the main channel of the Cruces River. Most of the tidal flats are located in the northern and southern sectors of the CRW. Those located in the middle and southern sectors of the study area exhibit denser coverage with vestigial tree trunks that evidence the former presence of marsh forests along the flooded shores. The texture of the studied sediments is dominated by sand (0.063-2 mm), followed by mud grain size fractions (<0.063 mm). The mud fraction is the only grain size showing significant differences between the studied tidal flats. Both the pH and ORP values vary significantly between sites and sampling periods. In general, ORP values were lower or negative in samples with higher mud and total organic matter contents collected mainly during both sampling times. These results set the first baseline for textural and basic geochemical characteristics of surface sediments from tidal flats in the Cruces River wetland. The database provides a primary tool for evaluating potential effects of possible alterations along the margins of the wetland, which is located in an area of the rapid development of forestry and industrial activities as well as urban expansion.

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Section: Discussionmentioning

confidence: 99%

Tidal flats of recent origin: distribution and sedimentological characterization in the estuarine Cruces River wetland, Chile

Manzano-Castillo

Jaramillo-Lopetegui²,

Pino³

2020

Lat. Am. J. Aquat. Res.

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“…As reported by Chung et al [11], the development of momentum in a vegetated patch is governed by the increased pressure at the canopy front, which occurs on a rapid timescale, while the development of turbulence requires the shear-induced structure above the canopy to grow in size until it reaches the water surface. The vegetation patch can also generate a tidal phase lag between the vegetated and adjacent bare flats with stronger flood currents in the vegetated zone and stronger ebb currents as on the adjacent bare flat [104].…”

Section: Hydrodynamics In the Edges Of Patchesmentioning

confidence: 99%

The World of Edges in Submerged Vegetated Marine Canopies: From Patch to Canopy Scale

Colomer

Serra

2021

Water

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This review describes the world of edges in submerged vegetated marine canopies (seagrasses, saltmarshes, and seaweeds) where an edge is a boundary with a frontal area separating the vegetation from the adjacent non-vegetated zones. Plants within the vegetation are made of flexible elements pronating in the direction of the flow and oscillating back and forth in response to wave forcing. Some of them also occupy the full height within the water body. The analysis focuses on both the canopy- and local-patch scales to acquire knowledge about the hydrodynamics and the biophysical interactions in the structural shallows and deep limits of the canopies as well as on the structural edges of vegetation patches and the edges in the gaps within the canopies. The spatial arrangements of both canopy and patch edges are not only well imposed through the modification of hydrodynamics, but so too through small-scale interactions from internal structural causes and modifications. The continuous fragmentation of coastal marine habitats has reduced their structural complexity, thus making habitat edges a prevalent seascape feature, including in the shallow (or upper) and deep (or lower) limits of the canopies, the patch edges, and the edges in the gaps within the canopies. Canopy patches represent a region of high flow resistance where flow deflects and accelerates above and/or next to the canopy, resulting in an increase in water velocity and turbulence, especially at the edges of the patch. At the edges, energy transfer is found in spectral wave velocities from the longer to shorter wave period components. Likewise, at the edges, the net deposition of sediments decreases over a distance to a certain length, relative to the bare bed, which is associated with a region of vertical updraft and elevated turbulent kinetic energy. The edge effects also relate to the influence that a patch edge can have on determining species composition and predation risk, which is additionally mediated by the effect the edges have on habitat complexity within the vegetated patch. Organism feedback within the edges does not simply follow the canopy and local features and, in fact, the intricate interaction between biogeophysical processes is key in explaining the complexity of coastal submerged canopy landscapes. For example, proximity to patch edges has a greater influence on epifaunal density and community structure than structural complexity or predation do. The extent to which edges reduce predation risk depends on the extent to which they support higher structural complexities compared to patch interiors. The canopies’ shallow limits and their position in the underwater beach profile are mostly limited by light availability, the intensity of the wave action, and the local nearshore hydrodynamics, but they also depend on the local structural conditions at the vegetated side. The deep limits of the canopies, however, mainly depend on the availability of light and research findings support migration both to the deeper and shallower layers. All structural edges face changes caused by increasing nutrient inputs, development of coastal zones and the increasing impact of climate change. A considerable challenge to managing, restoring, and conserving coastal marine ecosystems stems from understanding how the canopies are able to cope with these natural and anthropogenic disturbances.

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“…emerging structures at site 2; that would result in higher current velocities than at site 1, where vestigial tree trunks probably slow down current velocities and thus, promoting lower resuspension of sediments and concentrations of TSS (e.g. Friedrichs et al 2000, Perillo 2003, Bouma et al 2007, Ma et al 2014.…”

Section: Figure 3 Depth Of Inundation (Cm) (Continuous Blue Linementioning

confidence: 99%

Impact of a high rainfall event on the water level, current velocity, and total suspended solids in tidal flats environments of the estuarine Cruces River wetland, south-central Chile

Manzano

Jaramillo²,

Pino³

2021

Lat. Am. J. Aquat. Res.

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The effects of a sudden rainfall (40 mm d-1) event on the surface waters covering muddy tidal flats were studied during April 2016 at the estuarine Cruces River wetland in south-central Chile (~40ºS). The study area included flooded vestigial tree trunks, which is evidence of coseismic subsidence associated with the 1960 Valdivia earthquake as a source of environmental variability. The tidal flat with vestigial tree trunks registered the fastest and highest depth of inundation. In contrast, the tidal currents velocity and total suspended solids' concentrations were higher at the flat without trunks. Sudden rainfall events can significantly modify the characteristics of surface waters above sedimentary intertidal surfaces, where structures such as flooded trunks are present.

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Numerical study of sediment transport on a tidal flat with a patch of vegetation

Cited by 17 publications

References 34 publications

Tidal flats of recent origin: distribution and sedimentological characterization in the estuarine Cruces River wetland, Chile

Tidal flats of recent origin: distribution and sedimentological characterization in the estuarine Cruces River wetland, Chile

The World of Edges in Submerged Vegetated Marine Canopies: From Patch to Canopy Scale

Impact of a high rainfall event on the water level, current velocity, and total suspended solids in tidal flats environments of the estuarine Cruces River wetland, south-central Chile

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