PIE LTER Publications
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2019. Estimating Aboveground Biomass and Its Spatial Distribution in Coastal Wetlands Utilizing Planet Multispectral Imagery. Remote Sensing. 11
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2006. Experimental nutrient enrichment of a New England salt marsh: plant productivity and community composition responses. M.S.
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2010. Salt marsh geomorphological analyses via integration of multi-temporal multispectral remote sensing with LIDAR and GIS.. Journal of Coastal Research. 26:809-816.
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2015. An index to characterize the spatial distribution of land use within watersheds and implications for river network nutrient removal and export. Geophysical Research Letters. 42
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2013. Long-term nutrient enrichment elicits a weak density response by saltmarsh meiofauna. Hydrobiologia. 713:97-114.
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2016. A test of biological trait analysis with nematodes and an anthropogenic stressor. Environmental Monitoring and Assessment. 188
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2014. Long-term nutrient enrichment alters nematode trophic structure and body size in a Spartina alterniflora salt marsh. Marine Ecology. :1-16.
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2000. Salinity effects on tolerance and adaptation of estuarine nitrifying bacteria investigated by a plug-flux method. M.S.
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1999. Salinity effects on nitrogen dynamics in estuarine sediment investigated by a plug-flux method. Biological Bulletin. 197:287-288.
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2021. Biodiversity–productivity relationships are key to nature-based climate solutions. Nature Climate Change. 11:543–550.
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2016. Contributions of organic and inorganic matter to sediment volume and accretion in tidal wetlands at steady state. Earth's Future. 4:110-121.
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2015. Perspectives on a 30-Year Career of Salt Marsh Research. Long-Term Environmental Research: Changing the Nature of Scientists.
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2005. Analysis of size and complexity of randomly constructed food webs by information theoretic metrics.. Aquatic Food Webs: an Ecosystem Approach. :73-85.
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2010. Competition among marsh macrophytes by means of vertical geomorphological displacement. Third International Conference on Invasive Spartina. :109-115.
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2021. Marsh Equilibrium Theory: Implications for Responses to Rising Sea Level. Salt Marshes: Function, Dynamics, and Stresses. :157–177.
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2020. Tidal and Hurricane Impacts on Saltmarshes in the Northeastern Coastal and Barrier Network: Theory and Empirical Results. Estuaries and Coasts. 43:1658–1671.
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2013. Salt marsh primary production and its responses to relative sea level and nutrients. Oceanography. 26:78-84.
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2002. Responses of coastal wetlands to rising sea level. Ecology. 83:2869-2877.
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2013. Brinson Review: Perspectives on the influence of nutrients on the sustainability of coastal wetlands. Wetlands. 33:975-988.
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2005. Integrating LIDAR, multispectral imagery and neural network modeling techniques for marsh classification.. International Journal of Remote Sensing. 26:5221-5234.
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2007. Ecological engineering in intertidal saltmarshes.. Hydrobiologia. 577:161-168.
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2012. Assessment of Carbon Sequestration Potential in Coastal Wetlands.. Recarbonization of the Bioshpere: Ecosystem and Global Carbon Cycle. . :517-531.
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2005. Effects of changes in sea level and productivity on the stability of intertidal marshes.. UNESCO Proceeding Series on Lagoons and Coastal Wetlands in the Global Change Context: Impact and Management Issues. :121-127.