PIE LTER Publications
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2013. Ecogeomorphology of Salt Marshes. Treatise on Geomorphology. 12:180-200.
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2000. Ecophysiological controls on the growth of Spartina alterniflora. Concepts and Controversies in Tidal Marsh Ecology. :59-80.
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2000. Effects of sea level anomalies on estuarine processes.. Estuarine Science: A Synthetic Approach to Research and Practice. :107-127.
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2007. Estimating net primary production of salt marsh macrophytes. Principles and Standards for Measuring Primary Production. :106-119.
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2008. Nitrogen Dynamics of Coastal Salt Marshes. Nitrogen in the Marine Environment, 2nd Edition. :991-1036.
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2000. Salt marsh ecosystem support of marine transient species.. Concepts and Controversies in Tidal Marsh Ecology. :333-365.
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2012. South Atlantic Tidal Wetlands. Wetland Habitats of North America: Ecology and Conservation Concerns. :45-61.
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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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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.
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2004. The effects of long term nutrient addition on a salt marsh community.. New England Estuarine Research Society (NEERS), March 7-9, 2004.
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2004. The Salt Marsh Geomorphology: Physical and Ecological Effects on Landform. AGU Chapman Conference. 86:57-58.
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2004. What makes mummichogs grow? The relationship between growth rates and gut contents of Fundulus heteroclitus held in enclosures along a salinity gradient in a New England salt marsh. New England Estuarine Research Society (NEERS).
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2009. Anammox in tidal marsh sediments: The role of salinity, nitrogen loading, and marsh vegetation. Estuaries and Coasts. 32:238-245.
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2020. Are elevation and open‐water conversion of salt marshes connected? Geophysical Research Letters. 47
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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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2006. Changes in salt marsh vegetation, Phragmites australis, and nekton in response to increased tidal flushing in a New England salt marsh.. Wetlands. 26:544-557.
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2012. Coastal eutrophication as a driver of salt marsh loss. Nature. 490:388-392.
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2004. Comparison of fish assemblages in tidal salt marsh creeks and in adjoining mudflat areas in the Tejo estuary.. Cahiers de Biologie Marine. 45:213-224.
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2006. Competition among marsh macrophytes by means of geomorphological displacement in the intertidal zone.. Estuarine and Coastal Shelf Science. 69:395-402.
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2018. Constraining Marsh Carbon Budgets Using Long-Term C Burial and Contemporary Atmospheric CO2 Fluxes. Journal of Geophysical Research: Biogeosciences. 123:867-878.
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2020. Determining the drivers of suspended sediment dynamics in tidal marsh-influenced estuaries using high-resolution ocean color remote sensing. Remote Sensing of Environment. 240
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2000. Differences in properties of salt marsh sediment between hayed and reference sites. Biological Bulletin. 199:225-226.
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2020. Divergence of Sediment Fluxes Triggered by Sea-Level Rise Will Reshape Coastal Bays. Geophysical Research Letters. 47:e2020GL087862.
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2008. Do spur-throated grasshoppers, Melanoplus spp. (Orthoptera: Acrididae), exert top-down control on smooth cordgrass Spartinaalterniflora in northern New England? Estuaries and Coasts. 31:912-919.
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2010. The effect of increased nitrate loading on nitrate reduction via denitrification and DNRA in salt marsh sediments. Limnology and Oceanography. 55:789-802.