PIE LTER Publications
Creating spatially-explicit lawn maps without classifying remotely sensed imagery: The case of suburban Boston, Massachusetts, USA. Cities and the Environment. 7
.
2014. .
2014. Controls on the variability of organic matter and dissolved inorganic carbon age in northeast U.S. rivers. Marine Chemistry. 92:353-366.
.
2004. Controls of Chloride Loading and Impairment at the River Network Scale in New England. Journal of Environmental Quality. 47:839–847.
.
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. The contribution of agricultural and urban activities to inorganic carbon fluxes within temperate watersheds.. Chemical Geology. 266:318-327.
.
2009. Consumer control and abiotic stresses constrain coastal saltmarsh restoration. Journal of Environmental Management. 274:111110.
.
2020. Constraining Marsh Carbon Budgets Using Long-Term C Burial and Contemporary Atmospheric CO2 Fluxes. Journal of Geophysical Research: Biogeosciences. 123:867-878.
.
2018. Consequences of climate change on the ecogeomorphology of coastal wetlands. Estuaries and Coasts. 31:477-491.
.
2008. .
2021. Component intensities to relate difference by category with difference overall. International Journal of Applied Earth Observation and Geoinformation.
.
2019. Component intensities to relate difference by category with difference overall. International Journal of Applied Earth Observation and Geoinformation. 77:94–99.
.
2019. Competition among marsh macrophytes by means of geomorphological displacement in the intertidal zone.. Estuarine and Coastal Shelf Science. 69:395-402.
.
2006. Comparison of Intensity Analysis and the land use dynamic degrees to measure land changes outside versus inside the coastal zone of Longhai, China. Ecological Indicators. 89:336–347.
.
2018. Comparison of Intensity Analysis and the land use dynamic degrees to measure land changes outside versus inside the coastal zone of Longhai, China. Ecological Indicators. 89:336-347.
.
2018. 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.
.
2004. Coastal Wetland Resilience, Accelerated Sea-Level Rise, and the Importance of Timescale. AGU Advances. 2:e2020AV000334.
.
2021. Coastal Wetland Resilience, Accelerated Sea‐Level Rise, and the Importance of Timescale. AGU Advances. 2
.
2021. Coastal eutrophication as a driver of salt marsh loss. Nature. 490:388-392.
.
2012. Climate variability masks the impacts of land use change on nutrient export in a suburbanizing watershed. Biogeochemistry.
.
2014. A climate migrant escapes its parasites. Marine Ecological Progress Series. 641:111-121.
.
2020. Climate Change Implications for Tidal Marshes and Food Web Linkages to Estuarine and Coastal Nekton. Estuaries and Coasts. 44:1637–1648.
.
2021. Classification mapping of salt marsh vegetation byflexible monthly NDVItime-series using Landsat imagery. Estuarine and Coastal Shelf Science. 213:61-80.
.
2018. Chronic nutrient enrichment increases the density and biomass of the mudsnail, Nassarius obsoletus.. Estuaries and Coasts. 36:28-35.
.
2013. Characterizing a New England Saltmarsh with NASA G-LiHT Airborne Lidar. Remote Sensing. 11:509-539.
.
2019.