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Diurnal cycle of precipitation over the tropics and central United States: intercomparison of general circulation models
Name:
GASS_DCP_GCM.pdf
Embargo:
2024-12-08
Size:
4.638Mb
Format:
PDF
Description:
Final Accepted Manuscript
Author
Tao, ChengXie, Shaocheng
Ma, Hsi‐Yen
Bechtold, Peter
Cui, Zeyu
Vaillancourt, Paul A.
Van Weverberg, Kwinten
Wang, Yi‐Chi
Wong, May
Yang, Jing
Zhang, Guang J.
Choi, In‐Jin
Tang, Shuaiqi
Wei, Jiangfeng
Wu, Wen‐Ying
Zhang, Meng
Neelin, J. David
Zeng, Xubin
Affiliation
University of ArizonaIssue Date
2023-12-08
Metadata
Show full item recordPublisher
WileyCitation
Tao, C., Xie, S., Ma, H. Y., Bechtold, P., Cui, Z., Vaillancourt, P. A., ... & Zeng, X. (2024). Diurnal cycle of precipitation over the tropics and central United States: intercomparison of general circulation models. Quarterly Journal of the Royal Meteorological Society.Rights
© 2023 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
Diurnal precipitation is a fundamental mode of variability that climate models have difficulty in accurately simulating. Here the diurnal cycle of precipitation (DCP) in participating climate models from the Global Energy and Water Exchanges' DCP project is evaluated over the tropics and central United States. Common model biases such as excessive precipitation over the tropics, too frequent light-to-moderate rain, and the failure to capture propagating convection in the central United States still exist. Over the central United States, the issues of too weak rainfall intensity in climate runs is well improved in their hindcast runs with initial conditions from numerical weather prediction analyses. But the improvement is minimal over the central Amazon. Incorporating the role of the large-scale environment in convective triggering processes helps resolve the phase-locking issue in many models where precipitation often incorrectly peaks near noon due to maximum insolation over land. Allowing air parcels to be lifted above the boundary layer improves the simulation of nocturnal precipitation which is often associated with the propagation of mesoscale systems. Including convective memory in cumulus parameterizations acts to suppress light-to-moderate rain and promote intense rainfall; however, it also weakens the diurnal variability. Simply increasing model resolution (with cumulus parameterizations still used) cannot fully resolve the biases of low-resolution climate models in DCP. The hierarchy modeling framework from this study is useful for identifying the missing physics in models and testing new development of model convective processes over different convective regimes.Note
12 month embargo; first published 08 December 2023ISSN
0035-9009EISSN
1477-870XDOI
10.1002/qj.4629Version
Final accepted manuscriptSponsors
U.S. Department of Energyae974a485f413a2113503eed53cd6c53
10.1002/qj.4629