Lateral Marsh Edge Erosion as a Source of Sediments for Vertical Marsh Accretion. Journal of Geophysical Research.. 2018.
Contributions of organic and inorganic matter to sediment volume and accretion in tidal wetlands at steady state. Earth's Future. 4:110-121.. 2016.
Global environmental change and the nature of aboveground net primary productivity responses: insights from long‑term experiments. Oecologia.. 2015.
Ulva additions alter soil biogeochemistry and negatively impact Spartina alterniflora growth. Marine Ecological Progress Series. 532:59-72.. 2015.
Perspectives on a 30-Year Career of Salt Marsh Research. Long-Term Environmental Research: Changing the Nature of Scientists.. 2015.
Brinson Review: Perspectives on the influence of nutrients on the sustainability of coastal wetlands. Wetlands. 33:975-988.. 2013.
Ecogeomorphology of Salt Marshes. Treatise on Geomorphology. 12:180-200.. 2013.
Ecogeomorphology of Tidal Flats. Treatise on Geomorphology. 12:201-220.. 2013.
An Ecosystem Services Approach to Assessing the Impacts of the Deepwater Horizon Oil Spill in the Gulf of Mexico. :246.. 2013.
Salt marsh primary production and its responses to relative sea level and nutrients. Oceanography. 26:78-84.. 2013.
Assessment of Carbon Sequestration Potential in Coastal Wetlands.. Recarbonization of the Bioshpere: Ecosystem and Global Carbon Cycle. . :517-531.. 2012.
How does vegetation affect sedimentation on tidal marshes? Investigating particle capture and hydrodynamic controls on biologically mediated sedimentation Journal of Geophysical Research. 115. 2010.
Variability in dimethylsulfoniopropionate (DMSP) in Spartina alterniflora and its effect on Littoraria irrorata.. Marine Ecology Progress Series. 406:47-55.. 2010.
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.. 2009.
Latitudinal trends in Spartina alterniflora productivity and the response of coastal marshes to global change. Global Change Biology.. 2009.
Nutrient cycling relative to δ15N and δ13C natural abundance in a coastal wetland with long-term nutrient additions. Aquatic Ecology.. 2009.
Consequences of climate change on the ecogeomorphology of coastal wetlands. Estuaries and Coasts. 31:477-491.. 2008.
Estimating net primary production of salt marsh macrophytes. Principles and Standards for Measuring Primary Production. :106-119.. 2007.
Competition among marsh macrophytes by means of geomorphological displacement in the intertidal zone.. Estuarine and Coastal Shelf Science. 69:395-402.. 2006.
Analysis of size and complexity of randomly constructed food webs by information theoretic metrics.. Aquatic Food Webs: an Ecosystem Approach. :73-85.. 2005.
Distribution of phosphatase activity in marsh sediments along an estuarine salinity gradient.. Marine Ecological Progress Series. 292:75-83.. 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.. 2005.
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.. 2004.