Clouds can cool or warm the planet’s surface, a radiative effect that contributes significantly to the global energy balance and can be altered by human-made pollution. The southernmost ocean in the world, aptly named the Southern Ocean and far from human pollution but subject to abundant marine gases and aerosols, is about 80% covered by clouds. How does this body of water and its relationship to clouds contribute to global climate change?
Researchers are still working to figure it out, and they’re now one step closer, thanks to an international collaboration identifying compensation errors in widely used climate model protocols known as CMIP6. They published their findings on September 20 in Advances in atmospheric science.
“Cloud and radiation biases over the Southern Ocean have been a long-standing problem in recent generations of global climate models,” said corresponding author Yuan Wang, now an associate professor in the Department. of Earth, Atmospheric and Planetary Sciences at Purdue University. . “After the latest CMIP6 models were released, we were eager to see how they performed and if the old issues were still there.”
CMIP6, a project of the World Climate Research Program, enables the systematic evaluation of climate models to illuminate how they compare to each other and to real-world data. In this study, Wang and the researchers analyzed five of the CMIP6 models that aim to serve as standard references.
Wang said the researchers were also motivated by other studies in the field which indicate that cloud cover in the Southern Ocean is a contributing factor to the high sensitivity of some CMIP6 models, when the simulations predict a surface temperature that increases too rapidly for the increased radiation rate. . In other words, if simulated incorrectly, the clouds in the Southern Ocean can cast a shadow of doubt over the projection of future climate change.
“This paper emphasizes compensating for errors in cloud physical properties despite the overall improvement in radiation simulation over the Southern Ocean,” Wang said. “Through space-based satellite observations, we are able to quantify these errors in the microphysical properties of simulated clouds, including cloud fraction, cloud water content, cloud droplet size, etc., and to further reveal how each contributes to the total bias of the cloud radiative effect. ”
The radiative effect of clouds – how clouds interfere with radiation to warm or cool the surface – is largely determined by the physical properties of the cloud. “The radiative effects of clouds in CMIP6 are comparable to satellite observations, but we found that there are large compensation biases in the path of liquid water in the cloud fraction and the effective radius of the clouds. droplets,” Wang said. “The major implication is that while the latest CMIP models improve the simulation of their mean states, such as radiation fluxes at the top of the atmosphere, the detailed cloud processes are still highly uncertain.”
Wang says this discrepancy also partly explains why the model’s climate sensitivity ratings don’t perform as well, since those ratings rely on the model’s detailed physics — rather than average state performance — to assess the overall effect on the climate.
“Our future work will aim to identify the individual parameterizations responsible for these biases,” Wang said. “Hopefully we can work closely with the model developers to resolve them. After all, the ultimate goal of any model evaluation study is to help improve those models. »
Other contributors include Lijun Zhao and Yuk L. Yung, Division of Geology and Planetary Sciences, California Institute of Technology; Chuanfeng Zhao, Department of Atmospheric and Oceanic Sciences, School of Physics, Peking University; and Xiquan Dong, Department of Hydrology and Atmospheric Sciences, University of Arizona.
Advances in atmospheric science
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Compensating for errors in radiative and physical properties of clouds over the Southern Ocean in CMIP6 climate models
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