Assessment of Arctic and Antarctic sea ice predictability in CMIP5 decadal hindcasts

This paper examines the ability of coupled global climate models to predict decadal variability of Arctic and Antarctic sea ice. We analyze decadal hindcasts/predictions of 11 Coupled Model Intercomparison Project Phase 5 (CMIP5) models. Decadal hindcasts exhibit a large multimodel spread in the sim...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: Yang, Chao-Yuan, Liu, Jiping, Hu, Yongyun, Horton, Radley M., Chen, Liqi, Cheng, Xiao
Other Authors: Yang, CY (reprint author), SUNY Albany, Dept Atmospher & Environm Sci, Albany, NY 12222 USA., SUNY Albany, Dept Atmospher & Environm Sci, Albany, NY 12222 USA., Peking Univ, Sch Phys, Dept Atmospher & Ocean Sci, Beijing, Peoples R China., Columbia Univ, Ctr Climate Syst Res, New York, NY USA., NASA Goddard Inst Space Studies, New York, NY USA., SOA, Inst Oceanog 3, Key Lab Global Change & Marine Atmospher Chem, Xiamen, Peoples R China., Beijing Normal Univ, Coll Global Change & Earth Syst Sci, Beijing, Peoples R China.
Format: Journal/Newspaper
Language:English
Published: CRYOSPHERE 2016
Subjects:
MERIDIONAL OVERTURNING CIRCULATION
NORTH-ATLANTIC
SOUTHERN-OCEAN
CLIMATE MODEL
BERING-SEA
VARIABILITY
PREDICTION
TRENDS
EXTENT
TEMPERATURE
Antarctic
Arctic
Bering Sea
Pacific
Southern Ocean
The Antarctic
Antarc*
North Atlantic
Sea ice
Online Access:https://hdl.handle.net/20.500.11897/458696
https://doi.org/10.5194/tc-10-2429-2016
Description
Summary:This paper examines the ability of coupled global climate models to predict decadal variability of Arctic and Antarctic sea ice. We analyze decadal hindcasts/predictions of 11 Coupled Model Intercomparison Project Phase 5 (CMIP5) models. Decadal hindcasts exhibit a large multimodel spread in the simulated sea ice extent, with some models deviating significantly from the observations as the predicted ice extent quickly drifts away from the initial constraint. The anomaly correlation analysis between the decadal hindcast and observed sea ice suggests that in the Arctic, for most models, the areas showing significant predictive skill become broader associated with increasing lead times. This area expansion is largely because nearly all the models are capable of predicting the observed decreasing Arctic sea ice cover. Sea ice extent in the North Pacific has better predictive skill than that in the North Atlantic (particularly at a lead time of 3-7 years), but there is a reemerging predictive skill in the North Atlantic at a lead time of 6-8 years. In contrast to the Arctic, Antarctic sea ice decadal hindcasts do not show broad predictive skill at any timescales, and there is no obvious improvement linking the areal extent of significant predictive skill to lead time increase. This might be because nearly all the models predict a retreating Antarctic sea ice cover, opposite to the observations. For the Arctic, the predictive skill of the multi-model ensemble mean outperforms most models and the persistence prediction at longer timescales, which is not the case for the Antarctic. Overall, for the Arctic, initialized decadal hindcasts show improved predictive skill compared to uninitialized simulations, although this improvement is not present in the Antarctic. NOAA Climate Program Office [NA15OAR4310163, NA14OAR4310216]; NSFC [41676185] SCI(E) ARTICLE cyang4@albany.edu 5 2429-2452 10

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