Marsh Edge Erosion | ScienceGate

<em>Abstract.</em>—We examined the spatial and temporal variability of native and alien ichthyoplankton in three habitat types (marsh edge, shallow open-water, and river channel) in one reference and three restored marshes in the Sacramento–San Joaquin Delta, California, during 1998 and 1999. More than 6,700 fish embryos and 25,000 larvae represented by 10 families were collected in 240 tows during the 2-year study. Overall, the assemblage was dominated by alien fishes, but natives were more abundant during winter and spring, whereas aliens were more abundant during summer. Overall abundance was highest in marsh edge habitats, suggesting that this habitat provides favorable larval rearing habitats for many fishes. The reference marsh was dominated by alien species making it difficult to assess whether it had attributes that promoted use by native fish. Ichthyoplankton abundance varied comparably at restored sites of similar configuration. The restored site, with minimal tidal exchange and greater lower trophic productivity, supported the highest densities of alien fish. We conclude that restoration projects in this region of the estuary must consider the potential impacts of alien fishes on natives and evaluate strategies designed to improve recruitment success of native fishes. Specifically, we suggest that restored wetlands that offer only winter and spring inundation periods may provide maximum benefits to natives while limiting access by many alien fishes regardless of specific habitat-use requirements.

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Investigating the impact of in situ soil organic matter degradation through porewater spectroscopic analyses on marsh edge erosion

Chemosphere ◽

10.1016/j.chemosphere.2020.129266 ◽

2021 ◽

Vol 268 ◽

pp. 129266

Author(s):

Michael P. Hayes ◽

Yadav Sapkota ◽

John R. White ◽

Robert L. Cook

Keyword(s):

Organic Matter ◽

Soil Organic Matter ◽

Organic Matter Degradation ◽

Marsh Edge ◽

Spectroscopic Analyses ◽

The Impact

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Effects of Marsh Edge Erosion in Coupled Barrier Island-Marsh Systems and Geometric Constraints on Marsh Evolution

Journal of Geophysical Research Earth Surface ◽

10.1029/2017jf004530 ◽

2018 ◽

Vol 123 (6) ◽

pp. 1218-1234 ◽

Cited By ~ 5

Author(s):

Rebecca Lauzon ◽

A. Brad Murray ◽

Laura J. Moore ◽

David C. Walters ◽

Matthew L. Kirwan ◽

...

Keyword(s):

Barrier Island ◽

Geometric Constraints ◽

Marsh Edge

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Lateral Marsh Edge Erosion as a Source of Sediments for Vertical Marsh Accretion

Journal of Geophysical Research Biogeosciences ◽

10.1029/2017jg004358 ◽

2018 ◽

Vol 123 (8) ◽

pp. 2444-2465 ◽

Cited By ~ 31

Author(s):

Charles S. Hopkinson ◽

James T. Morris ◽

Sergio Fagherazzi ◽

Wilfred M. Wollheim ◽

Peter A. Raymond

Keyword(s):

Marsh Edge ◽

Marsh Accretion

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Detecting the Morphology of Prograding and Retreating Marsh Margins—Example of a Mega-Tidal Bay

Remote Sensing ◽

10.3390/rs12010013 ◽

2019 ◽

Vol 12 (1) ◽

pp. 13

Author(s):

Guillaume Goodwin ◽

Simon Mudd

Keyword(s):

Salt Marsh ◽

Lidar Data ◽

Lateral Motion ◽

Vertical Accretion ◽

Marsh Edge ◽

The Future ◽

Change Event ◽

Event Magnitude ◽

Do So

Retreat and progradation make the edges of salt marsh platforms their most active features. If we have a single topographic snapshot of a marsh, is it possible to tell if some areas have retreated or prograded recently or if they are likely to do so in the future? We explore these questions by characterising marsh edge topography in mega-tidal Moricambe Bay (UK) in 2009, 2013 and 2017. We first map outlines of marsh platform edges based on lidar data and from these we generate transverse topographic profiles of the marsh edge 10 m long and 20 m apart. By associating profiles with individual retreat or progradation events, we find that they produce distinct profiles when grouped by change event, regardless of event magnitude. Progradation profiles have a shallow scarp and low relief that decreases with event magnitude, facilitating more progradation. Conversely, steep-scarped, high-relief retreat profiles dip landward as retreat reveals older platforms. Furthermore, vertical accretion of the marsh edge is controlled by elevation rather than its lateral motion, suggesting an even distribution of deposition that would allow bay infilling were it not limited by the migration of creeks. While we demonstrate that marsh edges can be quantified with currently available DTMs, oblique observations are crucial to fully describe scarps and better inform their sensitivity to wave and current erosion.

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Overview of Research into the Coastal Effects of the Macondo Blowout from the Coastal Waters Consortium: A GoMRI Consortium

International Oil Spill Conference Proceedings ◽

10.7901/2169-3358-2014.1.604 ◽

2014 ◽

Vol 2014 (1) ◽

pp. 604-617 ◽

Cited By ~ 1

Author(s):

Linda M Hooper-Bui ◽

Nancy N Rabalais ◽

Annette S Engel ◽

R Eugene Turner ◽

G McClenachan ◽

...

Keyword(s):

Microbial Diversity ◽

Coastal Waters ◽

Plant Biomass ◽

Vegetation Coverage ◽

Ammonia Oxidizer ◽

Tropical Storms ◽

Marsh Edge ◽

Oil Transport ◽

Barataria Bay ◽

Freshwater Diversions

ABSTRACT The Coastal Waters Consortium (CWC) led by Louisiana Universities Marine Consortium is one of eight Gulf of Mexico Research Initiative research consortia. The CWC focuses on: oil transport and fate, chemical evolution and biological degradation, and environmental effects.The following is an overview of a portion of the research conducted within the consortium. The consortium works in a system that was impacted by the Deepwater Horizon oil disaster and additionally impacted by freshwater diversions resulting in changes in salinity, tropical storms, and hurricanes. First, we conducted model simulations assessing oil transport into the Barataria Bay estuary, which indicate that easterly winds and feeding of the anticyclonic gyre in the Louisiana Bight pushed the oil into Barataria Bay. In subtidal sediments adjacent to oiled marshes, marsh detritus from eroding marsh edges eventually became entrained in the sediment column. Biotic impacts vary. The above-ground plant biomass appears healthy at the individual sampling sites; overall the most seaward (i.e., likely oil-impacted) areas of Terrebonne and Barataria Bay have shown, via satellite data, a distinct decline in marsh vegetation coverage since 2010. Oysters appear to be affected by predation and salinity variation. Microbial diversity from marsh-edge sediments is distinct from before and after the spill, and between unoiled and oiled marshes, with lower diversity in oiled marshes; but the greatest community composition shifts are in marshes affected by the freshwater diversions. Changes in microbial diversity in the water column at the stream-side edge of oiled marshes are extensive and are related to marsh edge erosion. In contrast, oiling of marshes had no impact on ammonia oxidizer or denitrifier abundances and on soil biogeochemical process rates 2+ years post-spill. Analysis of long-term offshore phytoplankton community and hypoxia data indicate some signal of the Macondo oil, but these components of the ecosystem remain mostly influenced by the fresh water and nutrients delivered by the Mississippi River. The consortium continues to work to tease apart oil impacts, effects of salinity, natural variation, and disturbance from tropical storms and hurricanes to determine the trajectory for health of shelf waters and Louisiana's marshes.

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