Thin-layer sediment placement (TLP) is a promising management tool for enhancing tidal marsh resilience to rising seas.
Resources
Resources
A repository of data, publications, tools, and other products from project teams, Science Collaborative program, and partners.
Displaying 1 - 10 of 10See Keywords and Reserves
This project overview describes a 2018 Catalyst project led by Grand Bay Reserve that developed standardized tools to quality-check, analyze, and visualize Surface Elevation Table data.
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This project overview describes a 2015 Collaborative Research project where Waquoit Bay Reserve is working with end users to test the applicability of a previously-developed model to accurately predict greenhouse gas fluxes across a wide range of coastal wetlands.
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This project overview describes a project led by Elkorn Slough National Estuarine Research Reserve to communicate the results of a recent national synthesis of NERR Sentinel Site data on marsh resilience to sea level rise.
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This project overview describes a 2011 Collaborative Research project that examined the relationship between salt marshes, climate change, and nitrogen pollution and developed tools to leverage the “blue carbon ” stored in wetlands to achieve broader management goals.
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This paper, published in Biological Conservation, describes an innovative approach developed by the NERRS to evaluate the ability of tidal marshes to thrive as sea levels rise.
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This project overview describes a 2015 Science Transfer project where the Northeast reserves developed and offered a series of teacher workshops focused on the story of climate change impacts on coastal habitats.
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This project overview describes a 2017 Collaborative Research project that tested the effectiveness of thin-layer sediment placement as a marsh adaptation strategy.
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This project overview describes a 2017-2020 Collaborative Research project that involved scientists and end users in Cape Cod, Massachusetts working together to develop decision-support tools for hydrological management strategies that promote sustainability and delivery of valuable ecosystem services under future sea level rise scenarios.
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This project overview describes a 2018 Catalyst project led by the University of New Hampshire that is synthesizing salt marsh vegetation and elevation data to improve coastal wetland management in New England.