PIE LTER Publications
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2016. A linear relationship between wave power and erosion determines salt-marsh resilience to violent storms and hurricanes. PNAS. 113:64-68.
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2016. Salt marsh erosion rates and boundary features in a shallow Bay. Journal of Geophysical Research: Earth Surface. 121:1861-1875.
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2014. How waves shape salt marshes. Geology.
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2021. Cross-habitat access modifies the ‘trophic relay’ in New England saltmarsh ecosystems. Food Webs. 29:e00206.
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2020. Habitat decoupling via saltmarsh creek geomorphology alters connection between spatially-coupled food webs. Estuarine, Coastal and Shelf Science. 241:106825.
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2020. Trophic niche size and overlap decreases with increasing ecosystem productivity. Oikos. 129:1303–1313.
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2002. Bacterioplankton Community Composition in Flowing Waters of the Ipswich River Watershed. Biological Bulletin. 203:251-252.
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2022. Biotic and abiotic factors control the geomorphic characteristics of channel networks in salt marshes. Limnology and Oceanography. 67:89–101.
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2021. Success of coastal wetlands restoration is driven by sediment availability. Communications Earth & Environment. 2:44.
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2022. Long-term variations in water discharge and sediment load of the Pearl River Estuary: Implications for sustainable development of the Greater Bay Area. Frontiers in Marine Science. 9
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2021. Mismatch between watershed effects and local efforts constrains the success of coastal salt marsh vegetation restoration. Journal of Cleaner Production. 292:126103.
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2020. Efficient tidal channel networks alleviate the drought-induced die-off of salt marshes: Implications for coastal restoration and management. Science of The Total Environment. 749:141493.
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2021. The Total Operating Characteristic from Stratified Random Sampling with an Application to Flood Mapping. Remote Sensing. 13:3922.
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2020. Consumer control and abiotic stresses constrain coastal saltmarsh restoration. Journal of Environmental Management. 274:111110.
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2013. Mummichog, Fundulus heteroclitus, responses to long-term, whole-ecosystem nutrient enrichment.. Marine Ecological Progress Series. 492:211-222.
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2011. Population-level responses of the mummichog, Fundulus heteroclitus, to chronic nutrient enrichment in a New England salt marsh. M.S.:75.
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2006. Turnover rates of nitrogen stable isotopes in the salt marsh mummichog, Fundulus heteroclitus, following a laboratory diet switch.. Oecologia. 147:391-395.
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2002. Effects of haying on salt marsh surface invertebrates. Biological Bulletin. 203:250-251.
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2023. Peat Decomposition and Erosion Contribute to Pond Deepening in a Temperate Salt Marsh. Journal of Geophysical Research: Biogeosciences. 128171052(214)
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2021. Soil Organic Carbon Development and Turnover in Natural and Disturbed Salt Marsh Environments. Geophysical Research Letters. 48
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2002. Comparison of the fate of dissolved organic matter in two coastal systems: Hog Island Bay, VA (USA) and Plum Island Sound, MA (USA). School of Marine Science. M.S.:89.
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2003. Tracing the flow of organic matter from primary producers to filter feeders in Ria Formosa Lagoon, Southern Portugal. Estuaries. 26:846-856.
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1999. Sources of organic matter in Ria Formosa revealed by stable isotope analysis. Acta Oecologica. 20:463-469.