Arctic regional methane fluxes by ecotope as derived using eddy covariance from a low-flying aircraft

The Arctic terrestrial and sub-sea permafrost region contains approximately 30 % of the global carbon stock, and therefore understanding Arctic methane emissions and how they might change with a changing climate is important for quantifying the global methane budget and understanding its growth in t...

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Bibliographic Details
Published in:Atmospheric chemistry and physics 2017-07, Vol.17 (13), p.8619-8633
Main Authors: Sayres, David S, Dobosy, Ronald, Healy, Claire, Dumas, Edward, Kochendorfer, John, Munster, Jason, Wilkerson, Jordan, Baker, Bruce, Anderson, James G
Format: Article
Language:English
Subjects:
Aerodynamics
Aircraft
Analytical methods
Arctic zone
Atmosphere
Atmospheric circulation
Atmospheric models
Carbon
Carbon dioxide
Climate change
Covariance
Eddy covariance
Emission measurements
Emissions
Environmental aspects
Flight
Fluctuations
Fluxes
Heterogeneity
Instruments
Landsat
Landsat satellites
Measurement
Methane
Methane budget
Methane emissions
Observations
Patchiness
Permafrost
Polar environments
Raw materials
Remote sensing
Rivers
Soil
Soil temperature
Soils
Spatial heterogeneity
Spectroscopy
Surface fluxes
Surface-ice melting
Terrestrial environments
Towers
Turbulence
Vegetation
Vortices
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Summary:The Arctic terrestrial and sub-sea permafrost region contains approximately 30 % of the global carbon stock, and therefore understanding Arctic methane emissions and how they might change with a changing climate is important for quantifying the global methane budget and understanding its growth in the atmosphere. Here we present measurements from a new in situ flux observation system designed for use on a small, low-flying aircraft that was deployed over the North Slope of Alaska during August 2013. The system combines a small methane instrument based on integrated cavity output spectroscopy (ICOS) with an air turbulence probe to calculate methane fluxes based on eddy covariance. We group surface fluxes by land class using a map based on LandSat Thematic Mapper (TM) data with 30 m resolution. We find that wet sedge areas dominate the methane fluxes with a mean flux of 2.1 µg m−2 s−1 during the first part of August. Methane emissions from the Sagavanirktok River have the second highest at almost 1 µg m−2 s−1. During the second half of August, after soil temperatures had cooled by 7 °C, methane emissions fell to between 0 and 0.5 µg m−2 s−1 for all areas measured. We compare the aircraft measurements with an eddy covariance flux tower located in a wet sedge area and show that the two measurements agree quantitatively when the footprints of both overlap. However, fluxes from sedge vary at times by a factor of 2 or more even within a few kilometers of the tower demonstrating the importance of making regional measurements to map out methane emissions spatial heterogeneity. Aircraft measurements of surface flux can play an important role in bridging the gap between ground-based measurements and regional measurements from remote sensing instruments and models.
ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-17-8619-2017