ARMACMEV

ARM Airborne Carbon Measurements (ARM-ACME V)

1 June 2015 - 15 September 2015

Lead Scientist: Sebastien Biraud

Observatory: AAF , NSA , OLI

Long-term airborne observations from the ARM Airborne Carbon Measurements (ARM-ACME) campaign and analysis of atmospheric trace gases in the Southern Great Plains contributed to research on regional carbon budgets, atmospheric dynamics, and satellite validation. Recently, the ARM-ACME project achieved the World Meteorological Organization precision goal of validated < 0.2 ppm precision for CO2, a first for airborne measurements. We continued our long-term airborne study of atmospheric composition and carbon cycling by conducting an exploratory campaign in the North Slope of Alaska (NSA). Atmospheric temperatures are warming faster in the Arctic than predicted by climate models. The impact of this warming on permafrost degradation is not well understood, but it is projected to increase carbon decomposition and greenhouse gas production (CO2 and/or CH4) by arctic ecosystems. Airborne observations of atmospheric trace gases, aerosols, and cloud properties at the North Slope of Alaska are improving our understanding of global climate, with the goal of reducing the uncertainty in global and regional climate simulations and projections. From June 1 through September 15, 2015, the ARM Aerial Facility deployed the Gulfstream-159 (G-1) research aircraft to fly over the North Slope of Alaska, with occasional vertical profiling to measure trace-gas concentrations between Prudhoe Bay, Oliktok Point, Barrow, Atqasuk, Ivotuk, and Toolik Lake. The aircraft payload included the Picarro and Los Gatos Research analyzers for continuous measurements of CO2, CH4, H2O, and CO, and N2O mixing ratios, and a 12-flask sampler for analysis of carbon-cycle gases (CO2, CO, CH4, N2O, 13CO2, 14CO2, carbonyl sulfide, and trace hydrocarbon species including ethane). The aircraft payload also included instruments for measuring aerosol properties (number size distribution, total number concentration, absorption, and scattering), cloud properties (droplet and ice size information), atmospheric thermodynamic state, and solar/infrared radiation. This research, supported by the U.S. Department of Energy’s (DOE) Atmospheric Radiation Measurement (ARM) Climate Research Facility and Terrestrial Ecosystem Science programs, built upon the results from the National Aeronautics and Space Administration (NASA) Carbon in Arctic Reservoirs Vulnerability Experiment missions (Miller et al. 2012), and the DOE Next-Generation Ecosystem Experiment Arctic project.