The Influence of Local Feedbacks and Northward Heat Transport on the Equilibrium Arctic Climate Response to Increased Greenhouse Gas Forcing

This study uses coupled climate model experiments to identify the influence of atmospheric physics [Community Atmosphere Model, versions 4 and 5 (CAM4; CAM5)] and ocean model complexity (slab ocean, full-depth ocean) on the equilibrium Arctic climate response to an instantaneous CO₂ doubling. In sla...

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Bibliographic Details
Published in:Journal of climate 2012-08, Vol.25 (16), p.5433-5450
Main Authors: Kay, Jennifer E., Holland, Marika M., Bitz, Cecilia M., Blanchard-Wrigglesworth, Edward, Gettelman, Andrew, Conley, Andrew, Bailey, David
Format: Article
Language:English
Subjects:
Ablation
Air temperature
Albedo
Arctic climates
Arctic clouds
Arctic sea ice
Atmosphere
Atmospheric models
Atmospheric physics
Atmospheric processes
Carbon dioxide
Climate
Climate change
Climate models
Convergence
Depth
Earth, ocean, space
Equilibrium
Exact sciences and technology
Experiments
External geophysics
Global warming
Greenhouse effect
Greenhouse gases
Heat
Heat flux
Heat transfer
Heat transport
Marine
Modelling
Ocean circulation models
Ocean models
Oceanic climates
Oceans
Physics
Radiative forcing
Sea ice
Seasons
SPECIAL CCSM Earth System Model CESM1 COLLECTION
Surface temperature
Surface-air temperature relationships
Temperature
Thermodynamic equilibrium
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Summary:This study uses coupled climate model experiments to identify the influence of atmospheric physics [Community Atmosphere Model, versions 4 and 5 (CAM4; CAM5)] and ocean model complexity (slab ocean, full-depth ocean) on the equilibrium Arctic climate response to an instantaneous CO₂ doubling. In slab ocean model (SOM) experiments using CAM4 and CAM5, local radiative feedbacks, not atmospheric heat flux convergence, are the dominant control on the Arctic surface response to increased greenhouse gas forcing. Equilibrium Arctic surface air temperature warming and amplification are greater in the CAM5 SOM experiment than in the equivalent CAM4 SOM experiment. Larger 2 × CO₂ radiative forcing, more positive Arctic surface albedo feedbacks, and less negative Arctic shortwave cloud feedbacks all contribute to greater Arctic surface warming and sea ice loss in CAM5 as compared to CAM4. When CAM4 is coupled to an active full-depth ocean model, Arctic Ocean horizontal heat flux convergence increases in response to the instantaneous CO₂ doubling. Though this increased ocean northward heat transport slightly enhances Arctic sea ice extent loss, the representation of atmospheric processes (CAM4 versus CAM5) has a larger influence on the equilibrium Arctic surface climate response than the degree of ocean coupling (slab ocean versus full-depth ocean). These findings underscore that local feedbacks can be more important than northward heat transport for explaining the equilibrium Arctic surface climate response and response differences in coupled climate models. That said, the processes explaining the equilibrium climate response differences here may be different than the processes explaining intermodel spread in transient climate projections.
ISSN:0894-8755
1520-0442
DOI:10.1175/jcli-d-11-00622.1