CO2 Flux Sensor System

March 22, 2017 in Carbon/greenhouse gases, Current Research Projects, Sediments

Anna Michel, Zoe Sandwith (WHOI)

Funding Source(s):          WHOI

Flux measurements using the eddy covariance technique

March 22, 2017 in Carbon/greenhouse gases, Current Research Projects, Sediments

Matthew Long, WHOI

Funding Source(s):     WHOI

Investigating Salt Marshes as a source of Alkalinity and Low pH, High CO2 water to the Ocean

March 22, 2017 in Carbon/greenhouse gases, Climate change/Sea level rise, Current Research Projects, Salt marsh

Kevin Kroeger, Meagan Gonneea (U.S. Geological Survey: Woods Hole Coastal and Marine Science Center)

Aleck Wang (WHOI)

Funding Source(s):                 USGS, NSF

In-situ ecosystem metabolism measured by eddy correlation

July 29, 2013 in Carbon/greenhouse gases, Current Research Projects, Hydrodynamics, Sediments

PI: Matthew Long, WHOI
Funding: WHOI

Greenhouse Gas Sensing in Coastal and Salt Marsh Environments

July 3, 2013 in Carbon/greenhouse gases, Climate change/Sea level rise, Current Research Projects, Salt marsh

PI: Anna Michel, Princeton University (WHOI in Fall 2012)
Funding: WHOI and submitted grants (NSF, MIT Seagrant)

 

The Impact of Nitrogen-loading on Salt Marsh Greenhouse Gas Fluxes

May 29, 2013 in Carbon/greenhouse gases, Climate change/Sea level rise, Current Research Projects, Featured Projects, Nitrogen, Salt marsh

DSC_0125PIs:  Serena Moseman-Valtierra, University of Rhode Island, Jianwu Tang, MBL Ecosystems Center, Kevin Kroeger, USGS-Woods Hole Science Center,
Funding: MIT Seagrant
The general goal for the project is to measure potential greenhouse gas (GHG) emissions and net CO2 uptake in coastal wetlands under a range of realistic nitrogen (N) loads and inundation (sea) levels. By meeting this goal, we aim to improve the information with which managers and policy makers can maintain and maximize ecosystem productivity, reduce harmful feedbacks of climate, and assess the potential for these ecosystems to enter C markets.

We will examine how GHG emissions from salt marshes vary along an existing gradient of anthropogenic N loading in Waquoit Bay, MA (WB-NERR). Further, we will test for relationships between N loads to the marshes and plant productivity. To investigate the influence of anticipated future increases in sea level, we will use existing gradients in marsh soil elevation (and therefore a gradient in soil water saturation and in frequency and duration of soil inundation) as a space-for-time substitution simulating future inundation of soils.

Carbon Management in Coastal Wetlands: Quantifying Carbon Storage and Greenhouse Gas Emissions by Tidal Wetlands to Support Development of a Greenhouse Gas Protocol and Economic Assessment

May 29, 2013 in Carbon/greenhouse gases, Climate change/Sea level rise, Current Research Projects, Featured Projects, Nitrogen, Salt marsh

wetlandsProject Lead: Alison Leschen, Waquoit Bay Reserve Manager
Collaborative Lead: Tonna-Marie Rogers, Waquoit Bay Coastal Training Program Coordinator
PIs: Jianwu Tang, MBL Ecosystems Center, Kevin Kroeger, USGS-Woods Hole Science Center, Neil K. Ganju, USGS-Woods Hole Science Center, Serena Moseman-Valtierra, University of RI, Omar Abdul-Aziz, Florida International Univ., Stephen Emmett-Mattox, Restore America’s Estuaries, Igino Emmer, Silvestrum, Stephen Crooks, Consultant to RAE, Pat Megonigal, Smithsonian ERC, Thomas Walker, Manomet CCS, Chris Weidman, Waquoit Bay Reserve Research Coordinator,
Funding: NERRS Science Collaborative

Increasing atmospheric concentrations of three major greenhouse gases (GHG) are the main drivers of climate change. Efforts to ameliorate rising levels of GHG include the protection and restoration of ecosystems that constitute major carbon (C) sinks and minor sources of CH4 and N2O emissions. Tidal marshes are prime candidates for such efforts as their sediments display  high C sequestration. Loss of wetlands through human impacts such as land conversion, sediment supply disruption, nutrient loading, and with sea level rise, reduces future sequestration capacity and places at risk stores of C that built up over past centuries. Improved management of coastal C and nitrogen (N), based upon sound science, is a critical first step towards mitigation of climate change and management of coastal ecosystems. Management must address N loading that has the dual impact of 1) contributing to climate change through production of N2O, and 2) reducing production of root and soil matter by plants which can decrease the C sequestration capacity and resilience of marshes to sea level rise. Recognition of the importance of coastal marine systems in terms of C storage has led to national and international efforts to place monetary value on preserving or restoring the “blue carbon” in those systems, analogous to the value placed on forests. The barrier to incorporation of tidal wetlands into C markets is the absence of agreed upon GHG offset protocols that set guidelines for monitoring and verification requirements for wetlands projects, and a lack of data and knowledge regarding C and GHG fluxes in wetlands to support model development.

The project goals are to provide scientific information that can inform both C and N management as well as wetlands protection and restoration strategies for supporting development of policy frameworks and market-based mechanisms to reduce GHG.

Project website: http://www.waquoitbayreserve.org/research-monitoring/salt-marsh-carbon-project/