Gregory Noe
Research Interests: Wetland ecosystem ecology, focusing on the interactive influences of hydrology, geomorphology, climate, and biology on nitrogen, phosphorus, carbon, and sediment biogeochemistry and transport in watersheds, as well as plant community ecology and restoration ecology.
Greg Noe has been a Research Ecologist with the U.S. Geological Survey in Reston, VA, since 2002, where he leads the Wetland Ecosystem Ecology & Biogeochemistry Laboratory (WEEBL) in the Florence Bascom Geoscience Center. Dr. Noe’s research centers on wetland ecosystem ecology and watershed processes. His dissertation research identified the complex controls on annual plant germination in the salt marshes of southern California. This was followed by post-doctoral research on phosphorus biogeochemistry and enrichment effects in the Florida Everglades. When joining the USGS, he started a research program on nutrient cycling, transport, and retention in wetlands associated with floodplains.
He is currently the Immediate Past President of the Society of Wetland Scientists, serves on the Science and Technical Advisory Committee of the Chesapeake Bay Program, serves on the editorial board of Wetlands and previously of Wetlands Ecology and Management, is the recipient of the President's Service Award from the Society of Wetland Scientists, and has served on the program committees of national and international scientific conferences and numerous graduate student committees. Greg is a recipient of the Meritorius Service Award from the Department of the Interior.
Current projects:
- Quantifying and modeling nutrient retention by riverine floodplains from site to watershed scales across the U.S.
- Evaluating the impacts of watershed restoration on water quality and stream health in the Chesapeake
- Identifying the effects of sea level rise, salinization, and sediment availability on tidal freshwater wetland ecosystem resilience along the Atlantic Coast
- Measuring the water quality functions in created wetlands, stream restoration projects, and floodplain restorations, and how to optimize their design
Science and Products
A method to quantify and value floodplain sediment and nutrient retention ecosystem services
Floodplains provide critical ecosystem services to local and downstream communities by retaining floodwaters, sediments, and nutrients. The dynamic nature of floodplains is such that these areas can both accumulate sediment and nutrients through deposition, and export material downstream through erosion. Therefore, estimating floodplain sediment and nutrient retention should consider the net flux
A floodplain continuum for Atlantic coast rivers of the Southeastern US: Predictable changes in floodplain biota along a river's length
Floodplain trapping and cycling compared to streambank erosion of sediment and nutrients in an agricultural watershed
Tidal extension and sea-level rise: recommendations for a research agenda
Increasing floodplain connectivity through urban stream restoration increases nutrient and sediment retention
Comparison of sediment and nutrient export and runoff characteristics from watersheds with centralized versus distributed stormwater management
Planting richness affects the recovery of vegetation and soil processes in constructed wetlands following disturbance
Storms, channel changes, and a sediment budget for an urban-suburban stream, Difficult Run, Virginia, USA
Salinity influences on aboveground and belowground net primary productivity in tidal wetlands
Richness, biomass, and nutrient content of a wetland macrophyte community affect soil nitrogen cycling in a diversity-ecosystem functioning experiment
Contemporary deposition and long-term accumulation of sediment and nutrients by tidal freshwater forested wetlands impacted by sea level rise
Head-of-tide bottleneck of particulate material transport from watersheds to estuaries
Science and Products
A method to quantify and value floodplain sediment and nutrient retention ecosystem services
Floodplains provide critical ecosystem services to local and downstream communities by retaining floodwaters, sediments, and nutrients. The dynamic nature of floodplains is such that these areas can both accumulate sediment and nutrients through deposition, and export material downstream through erosion. Therefore, estimating floodplain sediment and nutrient retention should consider the net flux