Importance of Regional Climate Model Grid Spacing for the Simulation of Heavy Precipitation in the Colorado Headwaters

Importance of Regional Climate Model Grid Spacing for the Simulation of Heavy Precipitation in the Colorado Headwaters

Summer and winter daily heavy precipitation events (events above the 97.5th percentile) are analyzed in regional climate simulations with 36-, 12-, and 4-km horizontal grid spacing over the headwaters of the Colorado River. Multiscale evaluations are useful to understand differences across horizonta...

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Bibliographic Details
Published in:Journal of climate 2013-07, Vol.26 (13), p.4848-4857
Main Authors: Prein, Andreas F., Holland, Gregory J., Rasmussen, Roy M., Done, James, Ikeda, Kyoko, Clark, Martyn P., Liu, Changhai H.
Format: Article
Language:eng
Subjects:
Climate
Climate models
Computer simulation
Convection
Datasets
Earth, ocean, space
Exact sciences and technology
External geophysics
Geophysics. Techniques, methods, instrumentation and models
Headwaters
Heavy precipitation
Horizontal
Meteorology
Modeling
Orography
Parameterization
Precipitation
Regional
Regional climate models
Regional climates
Seasons
Simulation
Simulations
Snow
Studies
Summer
Water in the atmosphere (humidity, clouds, evaporation, precipitation)
Winter
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Summary:Summer and winter daily heavy precipitation events (events above the 97.5th percentile) are analyzed in regional climate simulations with 36-, 12-, and 4-km horizontal grid spacing over the headwaters of the Colorado River. Multiscale evaluations are useful to understand differences across horizontal scales and to evaluate the effects of upscaling finescale processes to coarser-scale features associated with precipitating systems. Only the 4-km model is able to correctly simulate precipitation totals of heavy summertime events. For winter events, results from the 4- and 12-km grid models are similar and outperform the 36-km simulation. The main advantages of the 4-km simulation are the improved spatial mesoscale patterns of heavy precipitation (below ∼100 km). However, the 4-km simulation also slightly improves larger-scale patterns of heavy precipitation.
ISSN:0894-8755
1520-0442