非均匀饱和广义湿位涡在暴雨分析与预测中的应用

周玉淑; 曹洁; 王东海

非均匀饱和广义湿位涡在暴雨分析与预测中的应用

周玉淑^1,2,
曹洁^1,3,
王东海²

1.
中国科学院大气物理研究所云降水物理与强风暴实验室, 北京 100029
2.
中国气象科学研究院灾害天气国家重点实验室, 北京 100081
3.
中国科学院研究生院, 北京 100049

资助项目:

国家自然科学基金项目 40405007

中国科学院项目 KZCX2-YW-206-4

中国气象科学研究院灾害天气国家重点实验室开放课题 2006LASW05

中国科学院项目 KZCX2-SW-225

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出版历程
- 收稿日期: 2007-03-30
- 修回日期: 2007-07-11
- 刊出日期: 2007-12-31

Application of Generalized Moist Potential Vorticity in Non-uniformly Saturated Atmosphere to Torrential Rain Forecast

1.
Laboratory of Cloud-precipitation Physics and Severe Storms, Institute of Atmospheric Physics, CAS, Beijing 100029
2.
State Key Laboratory of Severe Weather, Chinese Academy of Meteorological Sciences, Beijing 100081
3.
Graduate School, CAS, Beijing 100049

摘要

摘要: 考虑实际大气非均匀饱和特性, 通过引入广义位温及广义湿位涡方程, 对华北暴雨和江淮梅雨锋暴雨的发生及落区进行了广义湿位涡异常的诊断分析, 表明暴雨形成时大气低层有广义湿位涡的异常出现。对广义湿位涡倾向的计算表明:它对暴雨的发生有一定指示作用, 因而可利用广义湿位涡的异常来识别暴雨的出现。
- 非均匀饱和;
- 广义湿位涡;
- 暴雨
Abstract: The introduction of generalized potential temperature and tendency equation of generalized moist potential vorticity into the thermodynamic framework is based on the non-uniform saturation of real atmosphere. The generalized moist potential vorticity (GMPV) equation is deduced by absorbing the generalized potential temperature. The water vapor and its gradient effect can be manifested in the GMPV equation, which indicates the convergence mechanism of water vapor at lower levels when torrential rain occurs. The GMPV anomaly is used in diagnostic studies of torrential rain both in North China and Yangtze River Basin. The results show that dynamic identification and forecasting of torrential rain from the perspective of generalized moist potential vorticity and its anomaly are effective, which maybe provide a new thought for the operational application of the GMPV.
- non-uniform saturation;
- generalized moist potential vorticity;
- torrential rain

HTML全文

图 1 2001年7月27日06:00地面6 h降水实况 (单位:mm)(a) 与850 hPa广义湿位涡 (单位:PVU; 阴影区是广义湿位涡值≥1.5 PVU的区域, 1 PVU=10 ^-6K·m³·kg ^-1·s ^-1)(b)

Fig. 1 Horizontal distribution of 6-hour precipitation from observation (unit:mm)(a), generalized moist potential vorticity at 850 hPa (unit:PVU; the shade area represents the generalized moist potential vorticity value≥1.5 PVU)(b) at 06:00 on July 27, 2001

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图 2 2003年7月9日00:00地面6 h降水实况 (单位:mm)(a) 与925 hPa广义湿位涡 (单位:PVU; 阴影区是广义湿位涡值≥1.5 PVU的区域)(b)

Fig. 2 Horizontal distribution of 6-hour precipitation from observation (unit:mm)(a), generalized moist potential vorticity at 925 hPa (unit:PVU, the shade area represents the generalized moist potential vorticity value≥1.5 PVU)(b) at 00:00 on July 9, 2003

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图 3 2001年7月27日06:00沿暴雨中心的广义湿位涡沿115°E垂直剖面 (a) 和沿37°N垂直剖面 (b)(单位:PVU)

Fig. 3 Meridional distribution along 115°E (a) and zonal distribution along 37°N (b) of generalized moist potential vorticity at 06:00 on July 27, 2001(unit:PVU)

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图 4 暴雨中心点不同高度处广义湿位涡倾向的时间演变 (单位:10 ^-8 PVU·s ^-1)(a)37°N, 115°E处2001年7月26日06:00—27日18:00, (b)33°N, 119°E处2003年7月7日18:00—9日06:00

Fig. 4 The generalized moist potential vorticity tendency evolution of the torrential rain center at 37°N, 115°E from 06:00 on July 26 to 18:00 on July 27, 2001 (a) and at 33°N, 119°E from 18:00 on July 7 to 06:00 on July 9, 2003 (b)(unit:PVU·s ^-1)

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