Thicker clouds and accelerated Arctic sea ice decline: The atmosphere‐sea ice interactions in spring

Observations show that increased Arctic cloud cover in the spring is linked with sea ice decline. As the atmosphere and sea ice can influence each other, which one plays the leading role in spring remains unclear. Here we demonstrate, through observational data diagnosis and numerical modeling, that...

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Bibliographic Details
Published in:Geophysical Research Letters
Other Authors: Huang, Yiyi (author), Dong, Xiquan (author), Bailey, David Anthony (author), Holland, Marika M. (author), Xi, Baike (author), DuVivier, Alice K. (author), Kay, Jennifer E. (author), Landrum, Laura (author), Deng, Yi (author)
Format: Article in Journal/Newspaper
Language:English
Published: 2019
Subjects:
Arctic
Sea ice
Online Access:https://doi.org/10.1029/2019GL082791
Description
Summary:Observations show that increased Arctic cloud cover in the spring is linked with sea ice decline. As the atmosphere and sea ice can influence each other, which one plays the leading role in spring remains unclear. Here we demonstrate, through observational data diagnosis and numerical modeling, that there is active coupling between the atmosphere and sea ice in early spring. Sea ice melting and thus the presence of more open water leads to stronger evaporation and promotes cloud formation that increases downward longwave flux, leading to even more ice melt. Spring clouds are a driving force in the disappearance of sea ice and displacing the mechanism of atmosphere‐sea ice coupling from April to June. These results suggest the need to accurately model interactions of Arctic clouds and radiation in Earth System Models in order to improve projections of the future of the Arctic. 1852977

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