The Impact of Sea-Ice Loss on Arctic Climate Feedbacks and Their Role for Arctic Amplification

Matthew Jenkins; Aiguo Dai

doi:10.1029/2021GL094599

The Impact of Sea-Ice Loss on Arctic Climate Feedbacks and Their Role for Arctic Amplification

Matthew Jenkins, Aiguo Dai

Hydrometeorological Applications Program

SUNY Albany

Research output: Contribution to journal › Article › peer-review

69 Scopus citations

Abstract

Sea-ice loss and radiative feedbacks have been proposed to explain Arctic amplification (AA)—the enhanced Arctic warming under increased greenhouse gases, but their relationship is unclear. By analyzing coupled CESM1 simulations with 1%/year CO₂ increases, we show that without large sea-ice loss and AA, the lapse rate, Planck, and surface albedo feedbacks are greatly reduced, while the positive water vapor feedback changes little. The positive Arctic lapse rate feedback, which results from enhanced surface warming rather than the high stability of Arctic air, and changes in atmospheric energy transport across the Arctic Circle are a result, not a cause, of AA; while the water vapor feedback also plays a minor role. Instead, AA results from enhanced winter oceanic heating associated with sea-ice loss that is aided by a positive surface albedo feedback in summer and positive cloud feedback in winter.

Original language	English
Article number	e2021GL094599
Journal	Geophysical Research Letters
Volume	48
Issue number	15
DOIs	https://doi.org/10.1029/2021GL094599
State	Published - Aug 16 2021

Keywords

AA
Arctic
amplification
climate change
feedback
radiative kernel

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10.1029/2021GL094599

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abstract = "Sea-ice loss and radiative feedbacks have been proposed to explain Arctic amplification (AA)—the enhanced Arctic warming under increased greenhouse gases, but their relationship is unclear. By analyzing coupled CESM1 simulations with 1\%/year CO2 increases, we show that without large sea-ice loss and AA, the lapse rate, Planck, and surface albedo feedbacks are greatly reduced, while the positive water vapor feedback changes little. The positive Arctic lapse rate feedback, which results from enhanced surface warming rather than the high stability of Arctic air, and changes in atmospheric energy transport across the Arctic Circle are a result, not a cause, of AA; while the water vapor feedback also plays a minor role. Instead, AA results from enhanced winter oceanic heating associated with sea-ice loss that is aided by a positive surface albedo feedback in summer and positive cloud feedback in winter.",

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AB - Sea-ice loss and radiative feedbacks have been proposed to explain Arctic amplification (AA)—the enhanced Arctic warming under increased greenhouse gases, but their relationship is unclear. By analyzing coupled CESM1 simulations with 1%/year CO2 increases, we show that without large sea-ice loss and AA, the lapse rate, Planck, and surface albedo feedbacks are greatly reduced, while the positive water vapor feedback changes little. The positive Arctic lapse rate feedback, which results from enhanced surface warming rather than the high stability of Arctic air, and changes in atmospheric energy transport across the Arctic Circle are a result, not a cause, of AA; while the water vapor feedback also plays a minor role. Instead, AA results from enhanced winter oceanic heating associated with sea-ice loss that is aided by a positive surface albedo feedback in summer and positive cloud feedback in winter.

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KW - radiative kernel

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The Impact of Sea-Ice Loss on Arctic Climate Feedbacks and Their Role for Arctic Amplification

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Keywords

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