A Case Study of Processes Impacting Precipitation Phase and Intensity during the Vancouver 2010 Winter Olympics
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- handle: 10670/1.dqhtxn
- Thériault, Julie M.; Rasmussen, Roy; Smith, Trevor; Mo, Ruping; Milbrandt, Jason A.; Brugman, Melinda M.; Joe, Paul; Isaac, George A.; Mailhot, Jocelyn et Denis, Bertrand (2012). « A Case Study of Processes Impacting Precipitation Phase and Intensity during the Vancouver 2010 Winter Olympics ». Weather and Forecasting, 27(6), pp. 1301-1325.
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http://archipel.uqam.ca/7957/
Ce document est lié à :
http://dx.doi.org/10.1175/WAF-D-11-00114.1
Ce document est lié à :
doi:10.1175/WAF-D-11-00114.1
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Topographic effects Precipitation Severe storms Valley mountain flows Mesoscale processes Numerical weather prediction forecastingCiter ce document
Julie M. Thériault et al., « A Case Study of Processes Impacting Precipitation Phase and Intensity during the Vancouver 2010 Winter Olympics », UQAM Archipel : articles scientifiques, ID : 10670/1.dqhtxn
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Accurate forecasting of precipitation phase and intensity was critical information for many of the Olympic venue managers during the Vancouver 2010 Olympic and Paralympic Winter Games. Precipitation forecasting was complicated because of the complex terrain and warm coastal weather conditions in the Whistler area of British Columbia, Canada. The goal of this study is to analyze the processes impacting precipitation phase and intensity during a winter weather storm associated with rain and snow over complex terrain. The storm occurred during the second day of the Olympics when the downhill ski event was scheduled. At 0000 UTC 14 February, 2 h after the onset of precipitation, a rapid cooling was observed at the surface instrumentation sites. Precipitation was reported for 8 h, which coincided with the creation of a nearly 0°C isothermal layer, as well as a shift of the valley flow from up valley to down valley. Widespread snow was reported on Whistler Mountain with periods of rain at the mountain base despite the expectation derived from synoptic-scale models (15-km grid spacing) that the strong warm advection would maintain temperatures above freezing. Various model predictions are compared with observations, and the processes influencing the temperature, wind, and precipitation types are discussed. Overall, this case study provided a well-observed scenario of winter storms associated with rain and snow over complex terrain.