Residence Time of a Highly Urbanized Estuary: Jamaica Bay, New York

A 12 4 mile beach erosion control and hurricane flood protection project includes Jamaica Bay and the Rockaway Inlet in the southwest corner of Long Island, New York«i The project would provide 6 1 miles of beach fill and floodwalls along the Atlantic Ocean shore and 6 3 miles of inland structures to tie back to high ground, including a 0 9 mile barrier across the inlet The barrier, with a 300 foot gated opening and a 300 foot ungated opening, would permit suppression of the design hurricane surge so as to eliminate the need of flood protection works within the bay Linear mathematical models were used to determine these openings Because of the limitation of these models to produce adequate data m the bay pertinent to environmental and ecological considerations, three hydraulic models were utilized General conclusions drawn from the hydraulic model test data are that the results of the mathematical models were upheld, a design storm with high peak is critical for determining the height of protection, a design storm with high volume rather than high peak plus rainfall runoff is critical in determining ungated openings and suppression of bay levels, and there is a combination of gated and ungated openings that would meet the flood protection, navigation, environmental and ecological objectives.

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Sediment starvation destroys New York City marshes’ resistance to sea level rise

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1715392115 ◽

2018 ◽

Vol 115 (41) ◽

pp. 10281-10286 ◽

Cited By ~ 17

Author(s):

Dorothy M. Peteet ◽

Jonathan Nichols ◽

Timothy Kenna ◽

Clara Chang ◽

James Browne ◽

...

Keyword(s):

New York ◽

New York City ◽

Sea Level Rise ◽

Sea Level ◽

York City ◽

Organic Sediment ◽

Jamaica Bay ◽

Structural Weakness ◽

Global Sea Level ◽

Matter Flux

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 density measurements and a detailed accretion model. Accretion rate is calculated using historical land use and pollution markers, through a wide variety of sediment core analyses including geochemical, isotopic, and paleobotanical analyses. We find that, since 1800 CE, urban development dramatically reduced the input of marsh-stabilizing mineral sediment. However, as mineral flux decreased, organic matter flux increased. While this organic accumulation increase allowed vertical accumulation to outpace sea level, reduced mineral content causes structural weakness and edge failure. Marsh integrity now requires mineral sediment addition to both marshes and subsurface channels and borrow pits, a solution applicable to drowning estuaries worldwide. Integration of marsh mineral/organic accretion history with modeling provides parameters for marsh preservation at specific locales with sea level rise.

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Impacts of climate change on hurricane flood hazards in Jamaica Bay, New York

Climatic Change ◽

10.1007/s10584-020-02932-x ◽

2020 ◽

Vol 163 (4) ◽

pp. 2153-2171

Author(s):

Reza Marsooli ◽

Ning Lin

Keyword(s):

New York ◽

Twentieth Century ◽

First Century ◽

Flood Hazards ◽

Flood Events ◽

Flood Level ◽

Jamaica Bay ◽

Late Twentieth ◽

Twenty First Century ◽

Late Twentieth Century

AbstractSea level rise (SLR) and tropical cyclone (TC) climatology change could impact future flood hazards in Jamaica Bay—an urbanized back-barrier bay in New York—yet their compound impacts are not well understood. This study estimates the compound effects of SLR and TC climatology change on flood hazards in Jamaica Bay from a historical period in the late twentieth century (1980–2000) to future periods in the mid- and late-twenty-first century (2030–2050 and 2080–2100, under RCP8.5 greenhouse gas concentration scenario). Flood return periods are estimated based on probabilistic projections of SLR and peak storm tides simulated by a hydrodynamic model for large numbers of synthetic TCs. We find a substantial increase in the future flood hazards, e.g., the historical 100-year flood level would become a 9- and 1-year flood level in the mid- and late-twenty-first century and the 500-year flood level would become a 143- and 4-year flood level. These increases are mainly induced by SLR. However, TC climatology change would considerably contribute to the future increase in low-probability, high-consequence flood levels (with a return period greater than 100 year), likely due to an increase in the probability of occurrence of slow-moving but intense TCs by the end of twenty-first century. We further conduct high-resolution coastal flood simulations for a series of SLR and TC scenarios. Due to the SLR projected with a 5% exceedance probability, 125- and 1300-year flood events in the late-twentieth century would become 74- and 515-year flood events, respectively, in the late-twenty-first century, and the spatial extent of flooding over coastal floodplains of Jamaica Bay would increase by nearly 10 and 4 times, respectively. In addition, SLR leads to larger surface waves induced by TCs in the bay, suggesting a potential increase in hazards associated with wave runup, erosion, and damage to coastal infrastructure.

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Effects of a Beach Nourishment Project in Jamaica Bay, New York, on Horseshoe Crab (Limulus polyphemus) Spawning Activity and Egg Deposition

Estuaries and Coasts ◽

10.1007/s12237-017-0337-8 ◽

2017 ◽

Vol 41 (4) ◽

pp. 974-987 ◽

Cited By ~ 4

Author(s):

Mark L. Botton ◽

Christina P. Colón ◽

John Rowden ◽

Susan Elbin ◽

Debra Kriensky ◽

...

Keyword(s):

New York ◽

Horseshoe Crab ◽

Beach Nourishment ◽

Limulus Polyphemus ◽

Spawning Activity ◽

Egg Deposition ◽

Jamaica Bay

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Building Resilience in an Urban Coastal Environment: Integrated, Science-Based Planning in Jamaica Bay, New York

10.7249/rr2193 ◽

2018 ◽

Cited By ~ 2

Author(s):

Jordan Fischbach ◽

Debra Knopman ◽

Heather Smith ◽

Philip Orton ◽

Eric Sanderson ◽

...

Keyword(s):

New York ◽

Coastal Environment ◽

Integrated Science ◽

Building Resilience ◽

Jamaica Bay

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Simulation of Water Age and Residence Time in New York Bight

Journal of Physical Oceanography ◽

10.1175/2009jpo4249.1 ◽

2010 ◽

Vol 40 (5) ◽

pp. 965-982 ◽

Cited By ~ 46

Author(s):

Weifeng G. Zhang ◽

John L. Wilkin ◽

Oscar M. E. Schofield

Keyword(s):

New York ◽

Surface Water ◽

Time Scales ◽

Residence Time ◽

Surface Waters ◽

River Discharge ◽

Long Island ◽

Water Age ◽

New York Bight ◽

Island Coast

Abstract The time scales on which river inflows disperse in the coastal ocean are relevant to a host of biogeochemical and environmental processes. These time scales are examined in a modeling study of the Hudson River plume on its entry to the New York Bight (NYB). Constituent-oriented age and residence-time theory is applied to compute two time scales: mean age, which is calculated from the ratio of two model tracers, and residence time, which is calculated using the adjoint of the tracer conservation equation. Spatial and temporal variability associated with river discharge and wind is investigated. High river discharge lowers surface water age and shortens residence time in the apex of the NYB. Easterly winds increase surface water age and extend the duration waters along the Long Island coast remain in the NYB apex. Southerly winds increase age along the New Jersey coast but drive a decrease in age of offshore surface waters and prolong the time that surface waters close to the New Jersey coast stay in the NYB apex. Residence time along the Long Island coast is high in spring and summer because of the retention of water north of the Hudson shelf valley. Patterns of modeled surface water age and an age proxy computed from the ratio of satellite-measured irradiance in two channels show qualitative agreement. A least squares fit gives a statistically significant empirical relationship between the band ratio and modeled mean age for NYB waters.

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