Evaluating modelled tropospheric columns of CH4, CO, and O3 in the Arctic using ground-based Fourier transform infrared (FTIR) measurements
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Published:2024-01-24
Issue:2
Volume:24
Page:1079-1118
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ISSN:1680-7324
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Container-title:Atmospheric Chemistry and Physics
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language:en
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Short-container-title:Atmos. Chem. Phys.
Author:
Flood Victoria A.ORCID, Strong KimberlyORCID, Whaley Cynthia H., Walker Kaley A.ORCID, Blumenstock ThomasORCID, Hannigan James W.ORCID, Mellqvist JohanORCID, Notholt Justus, Palm MathiasORCID, Röhling Amelie N.ORCID, Arnold Stephen, Beagley Stephen, Chien Rong-You, Christensen JesperORCID, Deushi MakotoORCID, Dobricic Srdjan, Dong XinyiORCID, Fu Joshua S.ORCID, Gauss Michael, Gong Wanmin, Langner Joakim, Law Kathy S.ORCID, Marelle Louis, Onishi Tatsuo, Oshima NagaORCID, Plummer David A., Pozzoli Luca, Raut Jean-ChristopheORCID, Thomas Manu A.ORCID, Tsyro SvetlanaORCID, Turnock StevenORCID
Abstract
Abstract. This study evaluates tropospheric columns of methane, carbon monoxide, and ozone in the Arctic simulated by 11 models. The Arctic is warming at nearly 4 times the global average rate, and with changing emissions in and near the region, it is important to understand Arctic atmospheric composition and how it is changing. Both measurements and modelling of air pollution in the Arctic are difficult, making model validation with local measurements valuable. Evaluations are performed using data from five high-latitude ground-based Fourier transform infrared (FTIR) spectrometers in the Network for the Detection of Atmospheric Composition Change (NDACC). The models were selected as part of the 2021 Arctic Monitoring and Assessment Programme (AMAP) report on short-lived climate forcers. This work augments the model–measurement comparisons presented in that report by including a new data source: column-integrated FTIR measurements, whose spatial and temporal footprint is more representative of the free troposphere than in situ and satellite measurements. Mixing ratios of trace gases are modelled at 3-hourly intervals by CESM, CMAM, DEHM, EMEP MSC-W, GEM-MACH, GEOS-Chem, MATCH, MATCH-SALSA, MRI-ESM2, UKESM1, and WRF-Chem for the years 2008, 2009, 2014, and 2015. The comparisons focus on the troposphere (0–7 km partial columns) at Eureka, Canada; Thule, Greenland; Ny Ålesund, Norway; Kiruna, Sweden; and Harestua, Norway. Overall, the models are biased low in the tropospheric column, on average by −9.7 % for CH4, −21 % for CO, and −18 % for O3. Results for CH4 are relatively consistent across the 4 years, whereas CO has a maximum negative bias in the spring and minimum in the summer and O3 has a maximum difference centered around the summer. The average differences for the models are within the FTIR uncertainties for approximately 15 % of the model–location comparisons.
Funder
Canadian Space Agency
Publisher
Copernicus GmbH
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