Fetch and distance from the bay control accretion and erosion patterns in Terrebonne marshes (Louisiana, USA)

Cortese, Luca; Fagherazzi, Sergio

doi:10.1002/esp.5327

Cited by 13 publications

(14 citation statements)

References 58 publications

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“…Spatial data of fractional floating vegetation (FAV) and fractional submerged vegetation (SAV) used to mask out areas that could be interpreted as wetlands were retrieved from the USGS website via (https://www.sciencebase.gov/catalog/item/606df312d34e-ae125e9c7647) (Couvillion, 2021a(Couvillion, , 2021b. Geomorphological data of distance from the channel, and distance from the bay used to derive the models were taken from Cortese and Fagherazzi (2022). Spatial data of leveed areas, which were masked out from the calculations can be downloaded via the National Levee Database (https:// levees.sec.usace.army.mil/).…”

Section: Data Availability Statementmentioning

confidence: 99%

Using Normalize Difference Vegetation Index to Infer Wetlands Salinity and Organic Contribution to Vertical Accretion Rates

Cortese,

Jensen,

Simard

et al. 2023

JGR Biogeosciences

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Vegetation is a key component controlling soil accretion in coastal wetlands through production of belowground organic matter and enhanced deposition of mineral sediments. Vegetation structure is a proxy for wetland health and degradation that can be monitored at large scales with remote sensing. Among different multispectral indices, the Normalized Difference Vegetation Index (NDVI) is generally used for this purpose. Using Google Earth Engine (GEE), NDVI time‐series are extracted around 45 monitoring stations of the Coastwide Reference Monitoring System (CRMS) located in Terrebonne Bay, Louisiana, USA. NDVI tends to increase from saline to freshwater wetlands. Using these NDVI observations and in situ measurements of salinity, soil accretion rates, and geomorphic metrics (i.e., elevation, distance from the bay or from the nearest channel bank), empirical models were developed to derive maps of organic mass accumulation rates and salinity. The analysis shows that NDVI can be used to reproduce the salinity gradient in Terrebonne Bay, as the index captures differences in vegetation cover, which depend on salinity. A negative relationship between NDVI and organic accumulation mass rates is also found, indicating that saline marshes tend to accumulate more organic material compared to fresh wetlands.

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Section: Data Availability Statementmentioning

confidence: 99%

Using Normalize Difference Vegetation Index to Infer Wetlands Salinity and Organic Contribution to Vertical Accretion Rates

Cortese,

Jensen,

Simard

et al. 2023

JGR Biogeosciences

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“…Their results, then, are not easily transferrable to the regional scales that remote sensing data can address. Conversely, studies that incorporate spatial datasets to examine wetland changes typically do not employ direct inputs for sedimentation and bioproductivity to derive accretion rate estimates (e.g., Craft et al., 2009), instead relying on other spatial variables and proxies such as channel distance and fetch (a proxy for wave‐driven sediment resuspension) to capture accretionary processes (Cortese & Fagherazzi, 2022). Remote sensing offers the ability to accurately model and map these factors that drive wetland accretion rates and thereby provide more accurate assessments of blue carbon storage and sequestration dynamics at regional and global scales.…”

Section: Introductionmentioning

confidence: 99%

Leveraging the Historical Landsat Catalog for a Remote Sensing Model of Wetland Accretion in Coastal Louisiana

et al. 2022

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A wetland's ability to vertically accrete—capturing sediment and biological matter for soil accumulation—is key for maintaining elevation to counter soil subsidence and sea level rise. Wetland soil accretion is comprised of organic and inorganic components largely governed by net primary productivity and sedimentation. Sea level, land elevation, primary productivity, and sediment accretion are all changing across Louisiana's coastline, destabilizing much of its wetland ecosystems. In coastal Louisiana, analysis from 1984 to 2020 shows an estimated 1940.858 km2 of total loss at an average rate of 53.913 km2/year. Here we hypothesize that remote sensing timeseries data can provide suitable proxies for organic and inorganic accretionary components to estimate local accretion rates. The Landsat catalog offers decades of imagery applicable to tracking land extent changes across coastal Louisiana. This dataset's expansiveness allows it to be combined with the Coastwide Reference Monitoring System's point‐based accretion data. We exported normalized difference vegetation index (NDVI) and red‐band surface reflectance data for every available Landsat 4–8 scene across the coast using Google Earth Engine. Water pixels from the red‐band were transformed into estimates of total suspended solids to represent sediment deposition—the inorganic accretionary component. NDVI values over land pixels were used to estimate bioproductivity—representing accretion's organic component. We then developed a Random Forest regression model that predicts wetland accretion rates (R2 = 0.586, MAE = 0.333 cm/year). This model can inform wetland vulnerability assessments and loss predictions, and is to our knowledge the first remote sensing‐based model that directly estimates accretion rates in coastal wetlands.

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“…The inorganic mass accumulation rates map is available via the ORNL DAAC Delta-X data portal at https://doi. org/10.3334/ORNLDAAC/2301 (Cortese & Fagherazzi, 2023). Data supporting the modeling are publicly Journal of Geophysical Research: Earth Surface 10.1029/2023JF007065…”

Section: Conflict Of Interestmentioning

confidence: 99%

Storm Impacts on Mineral Mass Accumulation Rates of Coastal Marshes

Cortese,

Zhang,

Simard

et al. 2024

JGR Earth Surface

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Coastal marsh survival may be compromised by sea‐level rise, limited sediment supply, and subsidence. Storms represent a fundamental forcing for sediment accumulation in starving marshes because they resuspend bottom material in channels and tidal flats and transport it to the marsh surface. However, it is unrealistic to simulate at high resolution all storms that occurred in the past decades to obtain reliable sediment accumulation rates. Similarly, it is difficult to cover all possible combinations of water levels and wind conditions in fictional scenarios. Thus, we developed a new method that derives long‐term deposition rates from short‐term deposition generated by a finite number of storms. Twelve storms with different intensity and frequency were selected in Terrebonne Bay, Louisiana, USA and simulated with the 2D Delft3D‐FLOW model coupled with the Simulating Waves Nearshore (SWAN) module. Storm impact was analyzed in terms of geomorphic work, namely the product of deposition and frequency. To derive the long‐term inorganic mass accumulation rates, the new method generates every possible combination of the 12 chosen storms and uses a linear model to fit modeled inorganic deposition with measured inorganic mass accumulation rates. The linear model with the best fit (highest R2) was used to derive a map of inorganic mass accumulation rates. Results show that a storm with 1.7 ± 1.6 years return period provides the largest geomorphic work, suggesting that the most impactful storms are those that balance intensity with frequency. Model results show higher accumulation rates in marshes facing open areas where waves can develop and resuspend sediments. This method has the advantage of considering only a few real scenarios and can be applied in any marsh‐bay system.

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Fetch and distance from the bay control accretion and erosion patterns in Terrebonne marshes (Louisiana, USA)

Cited by 13 publications

References 58 publications

Using Normalize Difference Vegetation Index to Infer Wetlands Salinity and Organic Contribution to Vertical Accretion Rates

Using Normalize Difference Vegetation Index to Infer Wetlands Salinity and Organic Contribution to Vertical Accretion Rates

Leveraging the Historical Landsat Catalog for a Remote Sensing Model of Wetland Accretion in Coastal Louisiana

Storm Impacts on Mineral Mass Accumulation Rates of Coastal Marshes

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