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Shipborne observations reveal contrasting Arctic marine, Arctic terrestrial and Pacific marine aerosol properties
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Shipborne observations reveal contrasting Arctic marine, Arctic terrestrial and Pacific marine aerosol properties
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Journal Article
Shipborne observations reveal contrasting Arctic marine, Arctic terrestrial and Pacific marine aerosol properties
2020
Overview
There are few shipborne observations addressing the factors influencing the
relationships of the formation and growth of aerosol particles with cloud
condensation nuclei (CCN) in remote marine environments. In this study, the
physical properties of aerosol particles throughout the Arctic Ocean and
Pacific Ocean were measured aboard the Korean icebreaker R/V Araon during
the summer of 2017 for 25 d. A number of new particle formation (NPF)
events and growth were frequently observed in both Arctic terrestrial and
Arctic marine air masses. By striking contrast, NPF events were not detected
in Pacific marine air masses. Three major aerosol categories are therefore
discussed: (1) Arctic marine (aerosol number concentration CN2.5: 413±442 cm−3), (2) Arctic terrestrial (CN2.5: 1622±1450 cm−3) and (3) Pacific marine (CN2.5: 397±185 cm−3), following air mass back-trajectory analysis. A major conclusion
of this study is not only that the Arctic Ocean is a major source of
secondary aerosol formation relative to the Pacific Ocean but also that
open-ocean sympagic and terrestrially influenced coastal ecosystems both
contribute to shaping aerosol size distributions. We suggest that terrestrial
ecosystems – including river outflows and tundra – strongly affect aerosol
emissions in the Arctic coastal areas, possibly more than anthropogenic
Arctic emissions. The increased river discharge, tundra emissions and
melting sea ice should be considered in future Arctic atmospheric
composition and climate simulations. The average CCN concentrations at a
supersaturation ratios of 0.4 % were 35±40 cm−3, 71±47 cm−3 and 204±87 cm−3 for Arctic marine, Arctic
terrestrial and Pacific marine aerosol categories, respectively. Our
results aim to help evaluate how anthropogenic and natural atmospheric
sources and processes affect the aerosol composition and cloud properties.
