Quantifying and Valuing Carbon and Nitrogen Sequestration as Ecosystem Services in Salt Marshes.. MS. 2020.
Tidal Wetland Gross Primary Production Across the Continental United States, 2000–2019.. Global Biogeochemical Cycles. 34. 2020.
Global-change controls on soil-carbon accumulation and loss in coastal vegetated ecosystems. Nature Geoscience. 12:685-692.. 2019.
Nitrate addition stimulates microbial decomposition of organic matter in salt marsh sediments. Global Change Biology.. 2019.
Lateral Marsh Edge Erosion as a Source of Sediments for Vertical Marsh Accretion. Journal of Geophysical Research.. 2018.
Nutrient Enrichment Alters Salt Marsh Fungal Communities and Promotes Putative Fungal Denitrifiers. Microbial Ecology.. 2018.
The role of nitrate as an electron acceptor in microbial decomposition of salt marsh sediment organic matter and implications for carbon storage. PhD. 2018.
Shallow ponds are biogeochemically distinct habitats in salt marsh ecosystems. Limnology and Oceanography.. 2018.
Ecosystem metabolism in salt marsh tidal creeks and ponds: Applying triple oxygen isotopes and other gas tracers to novel environments. PhD. 2017.
Shallow ponds are heterogeneous habitats within a temperate salt marsh ecosystem. Journal of Geophysical Research: Biogeosciences. 122. 2017.
Contributions of organic and inorganic matter to sediment volume and accretion in tidal wetlands at steady state. Earth's Future. 4:110-121.. 2016.
Limited effects of nutrient enrichment on bacterial carbon sources in salt marsh tidal creek sediments. Marine Ecological Progress Series. 544:107-130.. 2016.
Salt marsh persistence is threatened by predicted sea-level rise. Estuarine and Coastal Shelf Science. 181:93-99.. 2016.
Drivers of spatial and temporal variability in estuarine food webs. Marine Ecological Progress Series. 533:67-77.. 2015.
Removal of terrestrial dissolved organic carbon in aquatic ecosystems of a temperate river network. Geophysical Research Letters. 42. 2015.
Animating the Carbon Cycle. Ecosystems. 17:344-359.. 2014.
The Lotic Intersite Nitrogen Experiments: an example of successful ecological research collaboration.. Freshwater Science. 33:700-710.. 2014.
Use of receding horizon optimal control to solve MaxEP-based biogeochemistry problems. Beyond the Second Law: Entropy Production and Non-Equilibrium Systems. :337-359.. 2014.
The changing carbon cycle of the coastal ocean.. Nature. 504:61-70.. 2013.
Fluxes of water, sediments, and biogeochemical compounds in salt marshes. Ecological Processes.. 2013.
Long-Term Trends in Ecological Systems: A Basis for Understanding Responses to Global Change. . Technical Bulletin Number 1931:396.. 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.. 2013.