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Publication Date
13 August 2014

Cloud Catching Requires Persuasive Parameters

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A new study led by Pacific Northwest National Laboratory looked for which "tunable" variables were most influential in depicting various cloud types in a global atmospheric model. They found that different parameters influenced different types of clouds. For stratocumulus, low and clumpy clouds, the parameters that matter most appear in water and heat flux equations. For shallow cumulus, cotton-ball-like low clouds, the most influential parameters are those related to how the atmospheric vertical velocity is skewed. Their study was published in the Journal of Advances in Modeling Earth Systems.

Approach

In this study, PNNL researchers and their collaborators at the University of Wisconsin-Milwaukee, the National Center for Atmospheric Research, and the Institute of Atmospheric Physics in Beijing used a quasi-Monte Carlo sampling approach to explore 35 parameters in a newly implemented cloud parameterization called Cloud Layers Unified By Binormals, or CLUBB. In a generalized linear model, they studied how simulated cloud fields respond to different tunable parameters. They configured one instance of stratocumulus and two of shallow cumulus clouds at coarse and fine vertical resolutions using the single-column version of the Community Atmosphere Model (CAM5) to reduce computational cost.

This study improves understanding of the newly implemented CLUBB showing that among many tunable parameters, only a handful are influential. The researchers identified different influential parameters for different types of clouds. For example, in stratocumulus, it is those parameters that appear in water and heat flux equations. In shallow cumulus, the parameters related to the skewness of vertical velocity are influential. For stratocumulus clouds, the influential parameters are also sensitive to the version resolution is used.

The findings help reduce the number of tunable parameters in future studies of sensitivity and calibration in global simulations. The results show that a small subset of tunable parameters can explain most of the variance in simulated cloud fields in the single-column version of CAM5.

Impact

Clouds are some of the toughest atmospheric components to simulate because global climate is divided into a grid with cells that are 100 km (about 62 miles) wide. Covering much smaller spaces, clouds tend to be blurred out of that picture. Modelers use parameterizations, a computational approach to represent clouds and other small-scale processes such as turbulence, to capture the fine details. In effect, parameterizations act as a "stand in" for reality. Inside the parameterizations are many equations and parameters describing a particular characteristic or behavior of each component. Putting together the right mix of "well-tuned" parameters produces modeling results well-matched to the climate.

Point of Contact
Zhun Guo
Funding Program Area(s)
Acknowledgements

Sponsors: This study was supported by the U.S. Department of Energy's (DOE's) Office of Science Earth System Modeling program as part of the Scientific Discoveries through Advanced Computing project.

User Facility: The research used computing resources at the National Energy Research Scientific Computing Center, which is also supported by the DOE's Office of Science.

Research Team: Zhun Guo, Minghuai Wang, Yun Qian, Steve Ghan, Mikhail Ovchinnikov, Chun Zhao and Guang Lin, PNNL; Vincent E. Larson, University of Wisconsin-Milwaukee; Peter A. Bogenschutz, National Center for Atmospheric Research; Tianjun Zhou, Institute of Atmospheric Physics, Beijing

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