Anthropocene Survival of Southern New England’s Salt Marshes

Watson, E. B.; Raposa, Kenneth B.; Carey, Joanna C.; Wigand, Cathleen; Warren, Robert

doi:10.1007/s12237-016-0166-1

Cited by 47 publications

(38 citation statements)

References 68 publications

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“…Their upper threshold is similar to the .5-6 mm y À1 tipping point suggested in Figures 2 and 3. Also, Fujimoto et al (1996) estimated that the limit of organic accretion for Pacific mangroves was between 2 and 10 mm y À1 , and Watson et al (2017) declared that the future of RSLR had already arrived in New England salt marshes where recent SLR rates over the last 19 years were 4 to 6 mm y À1 and salt marsh losses over the last 3 to 4 decades were 0.4 to 0.44% y À1 . The rate of delta collapse later this century may be much faster than that of delta initiation during the mid-Holocene.…”

Section: Discussionmentioning

confidence: 99%

Sea-Level Rise Tipping Point of Delta Survival

Turner

Kearney

Parkinson

2018

Journal of Coastal Research

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Section: Discussionmentioning

confidence: 99%

Sea-Level Rise Tipping Point of Delta Survival

Turner

Kearney

Parkinson

2018

Journal of Coastal Research

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“…One important caveat of this approach, however, is that marshes accreting at the same rate of RSLR are not necessarily maintaining their areal extent through time. Indeed, horizontal processes such as marsh edge retreat (Mariotti & Fagherazzi, 2010) and channel widening (Deegan et al, 2012; Mariotti, 2018; Watson et al, 2016) could erode marshes independently of their vertical accretion. Furthermore, the formation and enlargement of ponds could cause marsh loss despite that the vegetated marsh platform keeps pace with RSLR (Mariotti, 2016).…”

Section: Salt Marshes and Sea Level Risementioning

confidence: 99%

Salt Marsh Dynamics in a Period of Accelerated Sea Level Rise

et al. 2020

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Salt marshes are dynamic systems able to laterally expand, contract, and vertically accrete in response to sea level rise. Here, we present the grand challenges that need to be addressed to fully characterize marsh morphodynamics. The review focuses on physical processes and quantitative models. Without predictive models, it is impossible to determine the future marsh evolution under accelerated sea level rise. In these models, one of the challenges is to resolve both horizontal and vertical dynamics within the same framework. Vertically, the marsh has to accumulate enough material to contrast rising water levels. Horizontally, marsh erosion at the ocean side must be compensated by landward expansion in forests, lawns, and agricultural fields. The dynamics of the marsh‐upland boundary are still not fully understood and will require more research in the upcoming years. The complexity of marsh vegetation is seldom captured in predictive models of marsh evolution. More research is needed to understand the effects of each species or species assemblages on hydrodynamics and sediment transport. Here, we further advocate that a sediment budget resolving all sediment fluxes in a marsh complex is the most important metric of marsh resilience. Characterization of these fluxes will enable to connect salt marshes to other landforms and to unravel feedbacks controlling the evolution of the entire coastal system. Current models of marsh evolution rely on sparse data sets collected at few locations. Novel remote sensing techniques will provide high‐resolution spatial data that will inform a new generation of computer models.

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“…Historically, salt marshes have displayed high rates of loss due to land reclamation and disturbances such as mosquito ditching [3,4]. Currently, salt marshes along the mid-Atlantic coastal region of the United States are at risk of loss due to sea level rise (SLR), eutrophication, nutrient enrichment, sediment availability, tidal range, and herbivory and human disturbances [5][6][7][8][9][10][11][12]. Recent [44].…”

Section: Introductionmentioning

confidence: 99%

High Spatial Resolution Remote Sensing for Salt Marsh Mapping and Change Analysis at Fire Island National Seashore

Campbell

Wang

2019

Remote Sensing

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Salt marshes are changing due to natural and anthropogenic stressors such as sea level rise, nutrient enrichment, herbivory, storm surge, and coastal development. This study analyzes salt marsh change at Fire Island National Seashore (FIIS), a nationally protected area, using object-based image analysis (OBIA) to classify a combination of data from Worldview-2 and Worldview-3 satellites, topobathymetric Light Detection and Ranging (LiDAR), and National Agricultural Imagery Program (NAIP) aerial imageries acquired from 1994 to 2017. The salt marsh classification was trained and tested with vegetation plot data. In October 2012, Hurricane Sandy caused extensive overwash and breached a section of the island. This study quantified the continuing effects of the breach on the surrounding salt marsh. The tidal inundation at the time of image acquisition was analyzed using a topobathymetric LiDAR-derived Digital Elevation Model (DEM) to create a bathtub model at the target tidal stage. The study revealed geospatial distribution and rates of change within the salt marsh interior and the salt marsh edge. The Worldview-2/Worldview-3 imagery classification was able to classify the salt marsh environments accurately and achieved an overall accuracy of 92.75%. Following the breach caused by Hurricane Sandy, bayside salt marsh edge was found to be eroding more rapidly (F1, 1597 = 206.06, p < 0.001). However, the interior panne/pool expansion rates were not affected by the breach. The salt marsh pannes and pools were more likely to revegetate if they had a hydrological connection to a mosquito ditch (χ2 = 28.049, p < 0.001). The study confirmed that the NAIP data were adequate for determining rates of salt marsh change with high accuracy. The cost and revisit time of NAIP imagery creates an ideal open data source for high spatial resolution monitoring and change analysis of salt marsh environments.

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Anthropocene Survival of Southern New England’s Salt Marshes

Cited by 47 publications

References 68 publications

Sea-Level Rise Tipping Point of Delta Survival

Sea-Level Rise Tipping Point of Delta Survival

Salt Marsh Dynamics in a Period of Accelerated Sea Level Rise

High Spatial Resolution Remote Sensing for Salt Marsh Mapping and Change Analysis at Fire Island National Seashore

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