2018
DOI: 10.1073/pnas.1715392115
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Sediment starvation destroys New York City marshes’ resistance to sea level rise

Abstract: New York City (NYC) is representative of many vulnerable coastal urban populations, infrastructures, and economies threatened by global sea level rise. The steady loss of marshes in NYC’s Jamaica Bay is typical of many urban estuaries worldwide. Essential to the restoration and preservation of these key wetlands is an understanding of their sedimentation. Here we present a reconstruction of the history of mineral and organic sediment fluxes in Jamaica Bay marshes over three centuries, using a combination of de… Show more

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Cited by 60 publications
(51 citation statements)
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“…To preserve marsh stability for a myriad of ecological and shoreline protection reasons, we advocate thin-layer mineral additions to replace the mineral supply that appears missing in both coastal (Peteet et al 2018) and riverine marshes. Enhanced removal of nitrogen from wastewater is extremely important because of the documented increased organic matter decomposition with higher nitrogen (Watson et al 2014, Bulseco et al 2019) and the evidence for decreased root and rhizome production in several salt marsh species (Deegan et al 2012, Wigand et al 2014).…”
Section: Carbon Sequestration With Climate and Human Impactmentioning
confidence: 99%
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“…To preserve marsh stability for a myriad of ecological and shoreline protection reasons, we advocate thin-layer mineral additions to replace the mineral supply that appears missing in both coastal (Peteet et al 2018) and riverine marshes. Enhanced removal of nitrogen from wastewater is extremely important because of the documented increased organic matter decomposition with higher nitrogen (Watson et al 2014, Bulseco et al 2019) and the evidence for decreased root and rhizome production in several salt marsh species (Deegan et al 2012, Wigand et al 2014).…”
Section: Carbon Sequestration With Climate and Human Impactmentioning
confidence: 99%
“…A striking recent multidecadal analysis of aerial salt marsh extent in Rhode Island shows a loss of 17.3% in a mere 40 years (Watson et al 2017b). This loss of potential C sequestration is threatening because the upper meters of tidal marshes in urban regions such as Jamaica Bay, NYC also sequester abundant heavy metals (Peteet et al 2018). The importance of preserving the integrity of New York's marshes is critical for these reasons as well as for biodiversity, storm protection, water quality, and nursery habitat.…”
Section: Introductionmentioning
confidence: 99%
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“…These marshes usually have a high organic content, and are sometimes affected by nutrients introduced via freshwater river diversions, which promotes poor rhizome and root growth (Kearney et al, 2011). Also sediment starvation can lead to increasing organic matter content, which results in structural weakness and edge failure (Peteet et al, 2018). Salt marshes rooted in mineral soils have much higher shear strengths, and are the most resilient wetlands to erosional storm impacts (Morton and Barras, 2011).…”
Section: Stability Of Salt Marshes During Stormsmentioning
confidence: 99%
“…If vegetation cannot immediately colonize restored lands due to prior land‐surface subsidence, the elevation of the marsh platform must ultimately be raised to provide the necessary conditions for plant growth. Vertical accretion (VA) is the natural process by which both inorganic sedimentation and organic accumulation raises and/or maintains the elevation of the marsh surface in the tidal frame, a process of great importance under continuous and accelerating sea‐level rise (Drexler ; Anisfeld ; Peteet et al ). If little vegetation is present, such accretion must occur chiefly from riverine and tidal allochthonous sources of inorganic and organic matter (Williams & Orr ; Neubauer ).…”
Section: Introductionmentioning
confidence: 99%