PIE LTER Publications
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2010. Variability in dimethylsulfoniopropionate (DMSP) in Spartina alterniflora and its effect on Littoraria irrorata.. Marine Ecology Progress Series. 406:47-55.
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2019. Short-term effect of simulated salt marsh restoration by sand-amendment on sediment bacterial communities. PLoS ONE. 14
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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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2009. Relationships Between Spartina alterniflora and Littoraria irrorata in a South Carolina Salt Marsh. Wetlands. 29:818-825.
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2003. Phosphorus Limitation of Coastal Ecosystem Processes. Science. 299
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2001. Occurrence and Ecological Implications of Pyrophosphate in Estuaries. Limnology and Oceanography. 46:1570-1577.
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2009. Nutrient cycling relative to δ15N and δ13C natural abundance in a coastal wetland with long-term nutrient additions. Aquatic Ecology.
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2000. Marsh nutrient export supplied by ground water discharge: Evidence from radium measurements. Global Biogeochemical Cycles. 14:167-176.
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2009. Latitudinal trends in Spartina alterniflora productivity and the response of coastal marshes to global change. Global Change Biology.
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2018. Lateral Marsh Edge Erosion as a Source of Sediments for Vertical Marsh Accretion. Journal of Geophysical Research.
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2015. Ulva additions alter soil biogeochemistry and negatively impact Spartina alterniflora growth. Marine Ecological Progress Series. 532:59-72.
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2009. Impact of the dynamic feedback between sedimentation, sea level rise, and biomass production on near surface marsh stratigraphy and carbon accumulation. Estuarine, Coastal and Shelf Science. 82:377-389.
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2010. How does vegetation affect sedimentation on tidal marshes? Investigating particle capture and hydrodynamic controls on biologically mediated sedimentation Journal of Geophysical Research. 115
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2015. Global environmental change and the nature of aboveground net primary productivity responses: insights from long‑term experiments. Oecologia.
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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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2005. Distribution of phosphatase activity in marsh sediments along an estuarine salinity gradient.. Marine Ecological Progress Series. 292:75-83.
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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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2008. Consequences of climate change on the ecogeomorphology of coastal wetlands. Estuaries and Coasts. 31:477-491.
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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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2013. Brinson Review: Perspectives on the influence of nutrients on the sustainability of coastal wetlands. Wetlands. 33:975-988.
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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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2015. Perspectives on a 30-Year Career of Salt Marsh Research. Long-Term Environmental Research: Changing the Nature of Scientists.
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2004. Flow, sedimentation, and biomass production on a vegetated salt marsh in South Carolina: toward a predictive model of marsh morphologic and ecologic evolution.. The Ecogeomorphology of Tidal Marshes. :165-187.
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2007. Estimating net primary production of salt marsh macrophytes. Principles and Standards for Measuring Primary Production. :106-119.