Pan-Arctic aerosol number size distributions: seasonality and transport patterns

The Arctic environment has an amplified response to global climatic change. It is sensitive to human activities that mostly take place elsewhere. For this study, a multi-year set of observed aerosol number size distributions in the diameter range of 10 to 500 nm from five sites around the Arctic Oce...

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Bibliographic Details
Published in:Atmospheric chemistry and physics 2017-07, Vol.17 (13), p.8101-8128
Main Authors: Freud, Eyal, Krejci, Radovan, Tunved, Peter, Leaitch, Richard, Nguyen, Quynh T, Massling, Andreas, Skov, Henrik, Leonard, Barrie
Format: Article
Language:English
Subjects:
Accumulation
Aerosol dynamics
Aerosol observations
Aerosols
Air
Air flow
Air parcels
Altitude
Amplification
Annual variations
Arctic aerosols
Arctic environments
Arctic haze
Arctic observations
Arctic research
Arctic sea ice
Arctic zone
Atmospheric models
Atmospheric transport
Autumn
Boundary layers
Chemistry
Climate and human activity
Climate change
Climate models
Cluster analysis
Haze
Ice
Ice edge
Ice environments
Low altitude
Meteorology
Oceans
Particle formation
Particulates
Polar environments
Pollutants
Precipitation
Precipitation patterns
Proximity
Rainfall
Regions
Research centers
Residence time
Scavenging
Sea ice
Seasonal variations
Seasonality
Spring (season)
Summer
Trajectories
Trajectory analysis
Transport
Trends
Troposphere
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Summary:The Arctic environment has an amplified response to global climatic change. It is sensitive to human activities that mostly take place elsewhere. For this study, a multi-year set of observed aerosol number size distributions in the diameter range of 10 to 500 nm from five sites around the Arctic Ocean (Alert, Villum Research Station – Station Nord, Zeppelin, Tiksi and Barrow) was assembled and analysed.A cluster analysis of the aerosol number size distributions revealed four distinct distributions. Together with Lagrangian air parcel back-trajectories, they were used to link the observed aerosol number size distributions with a variety of transport regimes. This analysis yields insight into aerosol dynamics, transport and removal processes, on both an intra- and an inter-monthly scale. For instance, the relative occurrence of aerosol number size distributions that indicate new particle formation (NPF) event is near zero during the dark months, increases gradually to  ∼ 40 % from spring to summer, and then collapses in autumn. Also, the likelihood of Arctic haze aerosols is minimal in summer and peaks in April at all sites.The residence time of accumulation-mode particles in the Arctic troposphere is typically long enough to allow tracking them back to their source regions. Air flow that passes at low altitude over central Siberia and western Russia is associated with relatively high concentrations of accumulation-mode particles (Nacc) at all five sites – often above 150 cm−3. There are also indications of air descending into the Arctic boundary layer after transport from lower latitudes.The analysis of the back-trajectories together with the meteorological fields along them indicates that the main driver of the Arctic annual cycle of Nacc, on the larger scale, is when atmospheric transport covers the source regions for these particles in the 10-day period preceding the observations in the Arctic. The scavenging of these particles by precipitation is shown to be important on a regional scale and it is most active in summer. Cloud processing is an additional factor that enhances the Nacc annual cycle.There are some consistent differences between the sites that are beyond the year-to-year variability. They are the result of differences in the proximity to the aerosol source regions and to the Arctic Ocean sea-ice edge, as well as in the exposure to free-tropospheric air and in precipitation patterns – to mention a few. Hence, for most purposes, aerosol observ
ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-17-8101-2017