Diagnosing the factors that contribute to the intermodel spread of climate feedback in CMIP6
Diagnosing the factors that contribute to the intermodel spread of climate feedback in CMIP6
The global surface temperature climate feedback parameter l varies significantly across climate models, and its real-world value remains uncertain. Studies have found that the sea surface temperature (SST) response pattern and atmospheric model physics can each affect the climate feedback parameter in historical and idealized warming simulations. In this study, we design and analyze a series of the targeted atmospheric global climate model (AGCM) experiments to quantify how much the SST (both the warming pattern and the base climatology) and atmospheric model physics contributes to the intermodel spread of the climate feedback parameter and cloud feedback in phase 6 of the Coupled Model Intercomparison Project (CMIP6). We use three AGCMs, HiRAM, AM2.5, and AM4, developed in the Geophysical Fluid Dynamics Laboratory (GFDL), which span a wide range of feedbacks in response to uniform surface warming. The three GFDL models indicate that historical patterns of SST change systematically alter l, supporting the hypothesized role for a “pattern effect” in historical climate sensitivity. However, we found that forcing one AGCM with the different CO2-induced SST warming patterns or model SST climatology from a suite of climate models from CMIP6 can only reproduce;10% the intermodel spread of CO2-induced l, while the atmospheric model used determines the magnitude of l (;45%). This underscores the role of atmospheric model physics in altering l, particularly the cloud-related schemes. In addition, we demonstrate that the nonlinear interaction between SST and AGCM has a nonnegligible role in affecting l.
Climate models, Coupled models, Model comparison, Model evaluation/performance, Sea surface temperature
663-674
Wang, Chenggong
01f40c65-016c-45c6-8665-32aa38aeeaaa
Yang, Wenchang
92efaf88-b625-49d1-bae4-5d4cd388bdf9
Vecchi, Gabriel
a0af73df-3944-4ef9-bb1e-08d1e90a603e
Zhang, Bosong
3cf380ca-5d9c-4b7b-91c5-dfe6b517f9a1
Soden, Brian J.
323c5e8a-3260-461f-992c-f417ce972b77
Chan, Duo
4c1278dc-7f39-4b67-b1cd-3f81f55f4906
1 February 2025
Wang, Chenggong
01f40c65-016c-45c6-8665-32aa38aeeaaa
Yang, Wenchang
92efaf88-b625-49d1-bae4-5d4cd388bdf9
Vecchi, Gabriel
a0af73df-3944-4ef9-bb1e-08d1e90a603e
Zhang, Bosong
3cf380ca-5d9c-4b7b-91c5-dfe6b517f9a1
Soden, Brian J.
323c5e8a-3260-461f-992c-f417ce972b77
Chan, Duo
4c1278dc-7f39-4b67-b1cd-3f81f55f4906
Wang, Chenggong, Yang, Wenchang, Vecchi, Gabriel, Zhang, Bosong, Soden, Brian J. and Chan, Duo
(2025)
Diagnosing the factors that contribute to the intermodel spread of climate feedback in CMIP6.
Journal of Climate, 38 (3), .
(doi:10.1175/JCLI-D-23-0528.1).
Abstract
The global surface temperature climate feedback parameter l varies significantly across climate models, and its real-world value remains uncertain. Studies have found that the sea surface temperature (SST) response pattern and atmospheric model physics can each affect the climate feedback parameter in historical and idealized warming simulations. In this study, we design and analyze a series of the targeted atmospheric global climate model (AGCM) experiments to quantify how much the SST (both the warming pattern and the base climatology) and atmospheric model physics contributes to the intermodel spread of the climate feedback parameter and cloud feedback in phase 6 of the Coupled Model Intercomparison Project (CMIP6). We use three AGCMs, HiRAM, AM2.5, and AM4, developed in the Geophysical Fluid Dynamics Laboratory (GFDL), which span a wide range of feedbacks in response to uniform surface warming. The three GFDL models indicate that historical patterns of SST change systematically alter l, supporting the hypothesized role for a “pattern effect” in historical climate sensitivity. However, we found that forcing one AGCM with the different CO2-induced SST warming patterns or model SST climatology from a suite of climate models from CMIP6 can only reproduce;10% the intermodel spread of CO2-induced l, while the atmospheric model used determines the magnitude of l (;45%). This underscores the role of atmospheric model physics in altering l, particularly the cloud-related schemes. In addition, we demonstrate that the nonlinear interaction between SST and AGCM has a nonnegligible role in affecting l.
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Published date: 1 February 2025
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Publisher Copyright:
Ó 2025 American Meteorological Society.
Keywords:
Climate models, Coupled models, Model comparison, Model evaluation/performance, Sea surface temperature
Identifiers
Local EPrints ID: 504144
URI: http://eprints.soton.ac.uk/id/eprint/504144
ISSN: 0894-8755
PURE UUID: d3bdc11a-ecad-4035-b1a0-8ec52a8eeb1f
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Date deposited: 27 Aug 2025 16:50
Last modified: 28 Aug 2025 02:24
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Contributors
Author:
Chenggong Wang
Author:
Wenchang Yang
Author:
Gabriel Vecchi
Author:
Bosong Zhang
Author:
Brian J. Soden
Author:
Duo Chan
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