Arctic Sea ice decline whiplash modes in winter investigated from a Pan-Arctic viewpoint: atmospheric drivers and feedbacks

Arctic Sea ice decline whiplash modes in winter investigated from a Pan-Arctic viewpoint: atmospheric drivers and feedbacks

The term ‘sea ice decline whiplash’ describes short-term abrupt sea ice decline, as determined falling below the 10th percentile of the probability density function of daily sea ice concentration (SIC) tendency. The leading SIC modes over pan-Arctic show significant locality and co-variability based...

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Bibliographic Details
Main Authors: Xia Hu, Zhina Jiang, Yao Yao, Guokun Dai
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:Environmental Research Communications
Subjects:
sea ice seesaw
local feedback
abrupt sea ice loss
external transportation
Online Access:https://doi.org/10.1088/2515-7620/adf949
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Summary:The term ‘sea ice decline whiplash’ describes short-term abrupt sea ice decline, as determined falling below the 10th percentile of the probability density function of daily sea ice concentration (SIC) tendency. The leading SIC modes over pan-Arctic show significant locality and co-variability based on empirical orthogonal function (EOF) analysis of sea ice decline whiplash days during winters of 1979–2020. The first and third EOFs correspond to a seesaw and an in-phase anomalous SIC pattern over the Davis Strait/Labrador Sea and the Greenland-northern Barents Sea, respectively. The second EOF shows a dipole pattern, with opposing SIC centers of action in the Bering Sea and the Sea of Okhotsk. These leading EOF modes may occur individually or occasionally simultaneously, which partially explains the spatial heterogeneity of short-term Arctic sea ice retreat. Regression analysis shows that the abrupt sea ice decline associated with these three leading EOF modes is closely related to the enhanced downward longwave radiation over sea ice-covered region due to heat transport from midlatitudes and large-scale condensation heating, in addition to the moist effect produced by the increased evaporation after sea ice decline. The surface turbulent heat flux, however, may indirectly melt the sea ice by heating the surrounding ice-free region mainly through anomalous downward surface sensible heat flux. Conversely, the melting sea ice may have a feedback on the tropospheric atmosphere over mid-high latitudes via anomalous upward surface latent heat flux, which depends on the specific sea ice decline whiplash mode. Our work emphasizes the joint effects of external heat and moisture transportation associated with atmospheric circulation and local vertical feedback of the short-term sea ice decline whiplash.
ISSN:2515-7620

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