The climate response to increased cloud liquid water over the Arctic in CESM1: a sensitivity study of Wegener–Bergeron–Findeisen process

The surface radiative imbalance has large impacts on the long-term trends and year-to-year variability of Arctic sea ice. Clouds are believed to be a key factor in regulating this radiative imbalance, whose underlying processes and mechanisms, however, are not well understood. Compared with observat...

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Bibliographic Details
Published in:Climate dynamics 2021-05, Vol.56 (9-10), p.3373-3394
Main Authors: Huang, Yiyi, Dong, Xiquan, Kay, Jennifer E., Xi, Baike, McIlhattan, Elin A.
Format: Article
Language:English
Subjects:
Arctic climates
Arctic clouds
Arctic Ocean
Arctic region
Arctic sea ice
Atlantic Ocean
Climate
Climate change
Climate system
Climatology
Clouds
Coupling
Crystals
Downwelling
Earth and Environmental Science
Earth Sciences
Earth system science
Environmental aspects
Evaporation
Geophysics/Geodesy
Global warming
Ice
Ice crystals
liquids
Oceanography
Oceans
Positive feedback
Radiation
Radiation-cloud interactions
Relative humidity
satellites
Sea ice
Short wave radiation
spring
Water
winter
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Summary:The surface radiative imbalance has large impacts on the long-term trends and year-to-year variability of Arctic sea ice. Clouds are believed to be a key factor in regulating this radiative imbalance, whose underlying processes and mechanisms, however, are not well understood. Compared with observations, the Community Earth System Model version 1 (CESM1) is known to underestimate Arctic cloud liquid water. Here, the following hypothesis is proposed and tested: this underestimation is caused by an overactive Wegener–Bergeron–Findeisen (WBF) process in model as too many supercooled liquid droplets are scavenged by ice crystals via deposition. In this study, the efficiency of the WBF process in CESM1 was reduced to investigate the Arctic climate response, and differentiate the responses induced by atmosphere–ocean–sea ice coupling and global warming. By weakening the WBF process, CESM1 simulated liquid cloud fractions increased, especially in winter and spring. The cloud response resulted in increased downwelling longwave flux and decreased shortwave flux at the surface. Arctic clouds and radiation in simulations with reduced WBF efficiency show a better agreement with satellite retrievals. In addition, both coupling and global warming amplify the cloud response to a less efficient WBF process, due to increased relative humidity and enhanced evaporation, respectively. As a response, the sea ice tends to melt over the North Atlantic Ocean, most likely caused by a positive feedback process between clouds, radiation and sea ice during non-summer months. These results improve our understanding of large-scale effects of the WBF process and the role of cloud liquid water in the Arctic climate system.
ISSN:0930-7575
1432-0894
DOI:10.1007/s00382-021-05648-5