PIE LTER Publications
.
2019. Metagenomics coupled with biogeochemical rates measurements provide evidence that nitrate addition stimulates respiration in salt marsh sediments.. Limnology and Oceanography. 65
.
2020. Metagenomics coupled with biogeochemical rates measurements provide evidence that nitrate addition stimulates respiration in salt marsh sediments. Limnology and Oceanography. 65
.
2011. Metapopulation structure of Vibrionaceae among coastal marine invertebrates. Environmental Microbiology. 13:265-275.
.
2008. A method for estimating pore water drainage from marsh soils using rainfall and well records. Estuarine, Coastal and Shelf Science. 79:51-58.
.
2009. A method for estimating surface transient storage parameters for streams with concurrent hyporheic storage. Water Resources Research. 45
.
2017. Methods to summarize change among land categories across time intervals. Journal of Land Use Science. 12:218-230.
.
2013. Microbes in nature are limited by carbon and energy: the starving-survival lifestyle in soil and consequences for estimating microbial rates. Frontiers in Terrestrial Microbiology.
.
2016. Microbial associations with macrobiota in coastal ecosystems: patterns and implications for nitrogen cycling. Frontiers in Ecology and the Environment. 14:200-208.
.
2004. Microbial biogeography along an estuarine salinity gradient: the combined influences of bacterial growth and residence time.. Applied and Environmental Microbiology. 70:1494-1505.
.
2023. Microbial chemolithoautotrophs are abundant in salt marsh sediment following long-term experimental nitrate enrichment. FEMS Microbiology Letters. 370(12881)
.
2011. Microbial community composition in salt marsh sediments resists perturbation by nutrient enrichment. The ISME Journal. 5:1540-1548.
.
2021. Mismatch between watershed effects and local efforts constrains the success of coastal salt marsh vegetation restoration. Journal of Cleaner Production. 292:126103.
.
2024. Mitigation policies buffer multiple climate stressors in a socio-ecological salt marsh habitat. Sustainability Science. 19(1):245-258.
.
2009. Modeling denitrification in aquatic sediments. Biogeochemistry. 93:159-178.
.
2001. Modeling land-use change in the Ipswich watershed, Massachusetts, USA. Agriculture, Ecosystems & Environment. 85:83-94.
.
2003. Modeling microbial consortiums as distributed metabolic networks. Biological Bulletin. 204:174-179.
.
2004. Modeling Nitrogen Transport in the Ipswich River Basin, Massachusetts, Using HSPF.. Journal of the American Water Resources Association. 40:1365-1384.
.
2022. Modeling the Dynamics of Salt Marsh Development in Coastal Land Reclamation. Geophysical Research Letters. 49:e2021GL095559.
.
2012. Modeling the effect of tides and waves on benthic biofilms.. Journal of Geophysical Research. 117
.
2000. Modeling the effects of land-use change on nitrogen biogeochemistry in the Ipswich watershed, Massachusetts. Biological Bulletin. 199:218-219.
.
2005. Molecular characterization of sulfate-reducing bacteria in a New England salt marsh.. Environmental Microbiology. 7:1175-1185.
.
2002. A monitoring protocol to assess tidal restoration of salt marshes on local and regional scales. Restoration Ecology. 10:556-563.
.
2020. On the morphology of radial sand ridges. Earth Surface Processes and Landforms. 45:2613–2630.
.
2011. A Multi-Scalar Approach to Theorizing Socio-Ecological Dynamics of Urban Residential Landscapes. Cities and the Environment . 4
.
2013. Mummichog, Fundulus heteroclitus, responses to long-term, whole-ecosystem nutrient enrichment.. Marine Ecological Progress Series. 492:211-222.