Connecting early summer cloud-controlled sunlight and late summer sea ice in the Arctic

Connecting early summer cloud-controlled sunlight and late summer sea ice in the Arctic

This study demonstrates that absorbed solar radiation (ASR) at the top of the atmosphere in early summer (May–July) plays a precursory role in determining the Arctic sea ice concentration (SIC) in late summer (August–October). The monthly ASR anomalies are obtained over the Arctic Ocean (65°N–90°N)...

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Bibliographic Details
Published in:Journal of geophysical research. Atmospheres Vol. 119; no. 19; pp. 11,087 - 11,099
Main Authors: Choi, Yong-Sang, Kim, Baek-Min, Hur, Sun-Kyong, Kim, Seong-Joong, Kim, Joo-Hong, Ho, Chang-Hoi
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 16-10-2014
Subjects:
Albedo
Anomalies
Arctic sea ice
Atmospheres
Climate change
Climate models
Clouds
Correlation coefficient
Geophysics
Global warming
Marine
Meteorology
Ocean-atmosphere interaction
Sea ice
Solar radiation
Summer
Sunlight
PN, Arctic Ocean
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Summary:This study demonstrates that absorbed solar radiation (ASR) at the top of the atmosphere in early summer (May–July) plays a precursory role in determining the Arctic sea ice concentration (SIC) in late summer (August–October). The monthly ASR anomalies are obtained over the Arctic Ocean (65°N–90°N) from the Clouds and the Earth's Radiant Energy System during 2000–2013. The ASR changes primarily with cloud variation. We found that the ASR anomaly in early summer is significantly correlated with the SIC anomaly in late summer (correlation coefficient, r ≈ −0.8 with a lag of 1 to 4 months). The region exhibiting high (low) ASR anomalies and low (high) SIC anomalies varies yearly. The possible reason is that the solar heat input to ice is most effectively affected by the cloud shielding effect under the maximum TOA solar radiation in June and amplified by the ice‐albedo feedback. This intimate delayed ASR‐SIC relationship is not represented in most of current climate models. Rather, the models tend to over‐emphasize internal sea ice processes in summer. Key Point Cloud‐controlled sunlight in June drives Arctic sea ice loss in August–October
Bibliography:ark:/67375/WNG-J11659L8-2
ArticleID:JGRD51731
istex:ED755A3E1B0F3758050E0808E00FA5F013A07FD9
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:2169-897X
2169-8996
DOI:10.1002/2014JD022013