Low clouds suppress Arctic air formation and amplify high-latitude continental winter warming

High latitude continents have warmed much more rapidly in recent decades than the rest of the globe, especially in winter, and the maintenance of warm, frost-free conditions in continental interiors in winter has been a long-standing problem of past equable climates. We use an idealized single-colum...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences
Main Authors: Cronin, Timothy W, Tziperman, Eli
Format: Article in Journal/Newspaper
Language:English
Published: Proceedings of the National Academy of Sciences 2015
Subjects:
global warming
polar amplification
cloud feedbacks
paleoclimate
Arctic
Climate change
Global warming
polar night
Online Access:http://nrs.harvard.edu/urn-3:HUL.InstRepos:25198700
https://doi.org/10.1073/pnas.1510937112
Description
Summary:High latitude continents have warmed much more rapidly in recent decades than the rest of the globe, especially in winter, and the maintenance of warm, frost-free conditions in continental interiors in winter has been a long-standing problem of past equable climates. We use an idealized single-column atmospheric model across a range of conditions to study the polar-night process of air mass transformation from high-latitude maritime air, with a prescribed initial temperature profile, to much colder high-latitude continental air. We find that a low-cloud feedback { consisting of a robust increase in the duration of optically thick liquid clouds with warming of the initial state { slows radiative cooling of the surface and amplifies continental warming. This low-cloud feedback increases the continental surface air temperature by roughly two degrees for each degree increase of the initial maritime surface air temperature, effectively suppressing Arctic air formation. The time it takes for the surface air temperature to drop below freezing increases nonlinearly to over 10 days for initial maritime surface air temperatures of 15-20C. These results, supplemented by an analysis of CMIP5 climate model runs which shows large increases in cloud water path and surface cloud longwave forcing in warmer climates, suggest that the \lapse rate feedback" in simulations of anthropogenic climate change may be related to the influence of low clouds on the stratification of the lower troposphere, and also indicate that optically thick stratus cloud decks could help to maintain frost-free winter continental interiors in equable climates. Earth and Planetary Sciences Engineering and Applied Sciences Proof

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