Long‐term single‐column model intercomparison of diurnal cycle of precipitation over midlatitude and tropical land
Author
Tang, ShuaiqiXie, Shaocheng
Guo, Zhun
Hong, Song‐You
Khouider, Boualem
Klocke, Daniel
Köhler, Martin
Koo, Myung‐Seo
Krishna, Phani Murali
Larson, Vincent E.
Park, Sungsu
Vaillancourt, Paul A.
Wang, Yi‐Chi
Yang, Jing
Daleu, Chimene L.
Homeyer, Cameron R.
Jones, Todd R.
Malap, Neelam
Neggers, Roel
Prabhakaran, Thara
Ramirez, Enver
Schumacher, Courtney
Tao, Cheng
Bechtold, Peter
Ma, Hsi‐Yen
Neelin, J. David
Zeng, Xubin
Affiliation
Department of Hydrology and Atmospheric Sciences, University of ArizonaIssue Date
2021-12-15
Metadata
Show full item recordPublisher
WileyCitation
Tang, S., Xie, S., Guo, Z., Hong, S.-Y., Khouider, B., Klocke, D., Köhler, M., Koo, M.-S., Krishna, P. M., Larson, V. E., Park, S., Vaillancourt, P. A., Wang, Y.-C., Yang, J., Daleu, C. L., Homeyer, C. R., Jones, T. R., Malap, N., Neggers, R., … Zeng, X. (2021). Long-term single-column model intercomparison of diurnal cycle of precipitation over midlatitude and tropical land. Quarterly Journal of the Royal Meteorological Society.Rights
© 2021 Royal Meteorological Society.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
General Circulation Models (GCMs) have for decades exhibited difficulties in modelling the diurnal cycle of precipitation (DCP). This issue can be related to inappropriate representation of the processes controlling sub-diurnal phenomena like convection. In this study, 11 single-column versions of GCMs are used to investigate the interactions between convection and environmental conditions, processes that control nocturnal convections, and the transition from shallow to deep convection on a diurnal time-scale. Long-term simulations are performed over two continental land sites: the Southern Great Plains (SGP) in the USA for 12 summer months from 2004 to 2015 and the Manacapuru site at the central Amazon (MAO) in Brazil for two full years from 2014 to 2015. The analysis is done on two regimes: afternoon convective regime and nocturnal precipitation regime. Most models produce afternoon precipitation too early, likely due to the missing transition of shallow-to-deep convection in these models. At SGP, the unified convection schemes better simulate the onset time of precipitation. At MAO, models produce the heating peak in a much lower level compared with observation, indicating too shallow convection in the models. For nocturnal precipitation, models that produce most of nocturnal precipitation all allow convection to be triggered above the boundary layer. This indicates the importance of model capability to detect elevated convection for simulating nocturnal precipitation. Sensitivity studies indicate that (a) nudging environmental variables towards observations has a minor impact on DCP, (b) unified treatment of shallow and deep convection and the capability to capture mid-level convection can help models better capture DCP, and (c) the interactions of the atmosphere with other components in the climate system (e.g. land) are also important for DCP simulations in coupled models. These results provide long-term statistical insights on which physical processes are essential in climate models to simulate DCP.Note
12 month embargo; first published: 29 November 2021ISSN
0035-9009EISSN
1477-870XDOI
10.1002/qj.4222Version
Final accepted manuscriptSponsors
National Science Foundation of Sri Lankaae974a485f413a2113503eed53cd6c53
10.1002/qj.4222