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[1]石鹏翔,刘海文,段伯隆,等.影响重庆夏季暴雨的中尺度低涡的气候学特征[J].成都信息工程大学学报,2016,(03):323-326.
 SHI Peng-xiang,LIU Hai-wen,DUAN Bo-long,et al.The Summery Heavy Rainfall Climatic Characteristics Associated with the Mesocale Low Vortex over Chongqing[J].Journal of Chengdu University of Information Technology,2016,(03):323-326.
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影响重庆夏季暴雨的中尺度低涡的气候学特征

成都信息工程大学学报[ISSN:1006-6977/CN:61-1281/TN] 卷: 期数: 2016年03期 页码: 323-326 栏目: 数理科学 出版日期: 2016-02-28
Title:
The Summery Heavy Rainfall Climatic Characteristics Associated with the Mesocale Low Vortex over Chongqing
文章编号:
2096-1618(2016)03-0305-06
作者:
石鹏翔1 刘海文123 段伯隆1 朱玉祥4
(1.成都信息工程大学大气科学学院 高原大气与环境四川省重点实验室,四川 成都 610225; 2.重庆市气象科学研究所,重庆 401147; 3.中国科学院大气物理研究所大气科学和地球流体学数值模拟国家重点实验室(LASG),北京 100029; 4.中国气象局气象干部培训学院,北京 100081)
Author(s):
SHI Peng-xiang1 LIU Hai-wen123 DUAN Bo-long1 ZHU Yu-xiang4
(1.College of Atmospheric Sciences, Chengdu University of Information Technology, Plateau Atmosphere and Environment Key Laboratory of Sichuan Province, Chengdu 610225, China; 2. Chongqing Institute of Meteorological Sciences, Chongqing 401147,China; 3.State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics, Institute of Atmospheric Physics, Chinese Academy of Sciences, Beijing 100029,China; 4.China Meteorological Administration Training Centre, Beijing 100081,China)
关键词:
气候学 中尺度低涡 重庆 暴雨 高空急流
Keywords:
climatology mesoscale low vortex chongqing heavy rainfall upper-level jet
分类号:
P463.3
文献标志码:
A
摘要:
为揭示对流层中低层中尺度低涡影响重庆夏季暴雨的可能原因,使用1979~2011年1°×1°的ECMWF再分析资料和重庆市逐日降水资料,采用天气学诊断、合成分析等方法,在对重庆低涡暴雨定义的基础上,从天气、气候学角度,对重庆低涡导致的重庆暴雨进行分析。结果表明,30余年来,重庆低涡导致的重庆暴雨共有26例,重庆低涡导致的暴雨降水量和暴雨次数在空间分布上并不相同,重庆低涡导致的暴雨降水量最大值主要位于重庆中南部,而重庆低涡暴雨次数最大值区域则主要位于重庆的西南。导致重庆夏季暴雨的重庆低涡在700 hPa上空主要为一个闭合的低压,重庆暴雨发生次数最多的地区主要位于从重庆垫江到南川槽线的西北部; 700 hPa上重庆西部的θse的“槽”和“脊”,使冷暖空气在重庆地区交汇,非常有利于重庆暴雨的发生。在对流层中层,和重庆低涡相对应的是一高空槽; 重庆暴雨主要位于高空急流出口区的右侧。重庆低涡垂直结构表明,其在对流层低层主要表现为气旋性辐合环流,在对流层中高层则为反气旋性辐散环流,这样的垂直空间配置,使重庆上空从对流层低层到对流层顶层附近,都为明显的上升运动; 强烈的上升运动和来自孟加拉湾、南海以及重庆西北部的水汽,使得重庆西边界、北边界以及南边界呈现为水汽输入边界,水汽在重庆地区辐合盈余,导致重庆夏季暴雨的发生。
Abstract:
In order to reveal the possible reason that the mesoscale low vortex in the lower troposphere affect the summer heavy rainfall in the Chongqing area, ECMWF reanalysis data and Chongqing daily precipitation data us the weather diagnosis and analysis synthesis methods ased on the definition of the Chongqing vortex heavy rainfall, then from the weather and climate perspective, the heavy rainfall caused by the Chongqing Vortex. The results show that, more than 30 years, the Chongqing Vortex have cased Chongqing heavy rainfall in a total of 26 cases. The precipitation and frequency of heavy rainfall caused by Chongqing vortex are not the same in the space distribution. The maximum of heavy rainfall precipitation is mainly located in the central and southern Chongqing, but the frequency maximum area is mainly located in the southwest Chongqing. On 700hPa the Chongqing vortex which caused Chongqing summer heavy rainfall is a closed low pressure. The region that Chongqing heavy rainfall occurrs most frequently is mainly located in the north-west of trough-line from Chongqing Dianjiang to Nanchuan. On 700hPa the θse "trough" in west Chongqing and its "ridge" over Chongqing make the intersection of cold and warm air in the Chongqing region, which is very conducive to Chongqing heavy rainfall occur. In the middle troposphere, corresponding to the Chongqing vortex is an upper trough. Chongqing heavy rainfall is mainly located in the right side of upper-level jet stream outlet zone. The Chongqing vortex vertical structure show that it is convergence cyclonic circulation in the lower troposphere and is divergent anticyclonic circulation in the upper troposphere, an obvious upward movement from the lower troposphere to top over Chongqing. The strong upward movement and the water moisture from the Bay of Bengal, South China Sea and the northwestern Chongqing moisture make the Chongqing west boundary, northern boundary and southern boundary appear as input border of water vapor, which lead to the moisture convergence and surplus and final result the summer heavy rainfall occur in Chongqing.

参考文献/References:

[1] 陶诗言,丁一汇,周晓平. 暴雨和强对流天气的研究[J]. 大气科学, 1979, 3(3):227-238.
[2] 赵思雄,周晓平,张可苏,等. 中尺度低压系统形成和维持的数值实验[J]. 大气科学, 1982, 6(2):109-117.
[3] 周晓平,赵思雄, 张宝严. 梅雨锋上中尺度低压发生的数值模拟实验[J]. 大气科学, 1984, 8(4):353-361.
[4] Bei Naifang, Zhao Sixiong, Gao Shouting. Numerical simulation of a heavy rainfall event in China during July 1998[J]. Meteorology & Atmospheric Physics, 2002, 80(1):153-164.
[5] 董佩明,赵思雄. 引发梅雨锋暴雨的频发型中尺度低压(扰动)的诊断研究[J]. 大气科学, 2004, 28(6):876-891.
[6] Schumacher R S, Johnson R H.Mesoscale Processes Contributing to Extreme Rainfall in a Midlatitude Warm-Season Flash Flood[J]. Monthly Weather Review, 2008, 136(10):3964-3986.
[7] James E P, Johnson R H. Patterns of Precipitation and Mesolow Evolution in Midlatitude Mesoscale Convective Vortices[J]. Mon.wea.rev, 2010, 138(3):909-931.
[8] 程麟生,冯伍虎. "987”突发大暴雨及中尺度低涡结构的分析和数值模拟[J]. 大气科学, 2001, 25(4):465-478.
[9] Galarneau T J, Bosart L F, Davis C A, et al. Baroclinic Transition of a Long-Lived Mesoscale Convective Vortex[J]. Monthly Weather Review, 2010, 137(2):562-584.
[10] Trier S B, Davis C A, Tuttle J D. Long-Lived Mesoconvective Vortices and Their Environment. Part I: Observations from the Central United States during the 1998 Warm Season[J]. Mon.wea.rev, 2010, 128(10):3376-3395.
[11] 张旭斌,张熠. 一次华南暴雨过程的数值模拟——中尺度对流系统形成发展机制[J]. 气象科学, 2011, 31(2):145-152.
[12] Li B, Liu L P, Zhao S X.The possible mechanism of a type of vortex heavy rainfall during the pre-rainy season in South China [J]. Atmospheric and Oceanic Science Letters,2011,4(5): 247–252.
[13] Kuo Y H, Cheng L, Anthes R A, et al. Mesoscale Analyses of the Sichuan Flood Catastrophe, 11-15 July 1981[J]. Monthly Weather Review, 1986, 114:1984-2003.
[14] 矫梅燕,李川,李延香. 一次川东大暴雨过程的中尺度分析[J]. 应用气象学报,2005,16(5): 701-704.
[15] 周国兵,隆宵, 刘毅. 重庆市"5·29"暴雨天气过程诊断分析与数值模拟[J]. 气象科技, 2006, 34(1):29-34.
[16] 赵思雄,傅慎明. 2004年9月川渝大暴雨期间西南低涡结构及其环境场的分析[J]. 大气科学, 2007, 31(6):1059-1075.
[17] 于波,林永辉. 引发川东暴雨的西南低涡演变特征个例分析[J]. 大气科学, 2008, 32(1):141-154.
[18] 陶诗言. 中国之暴雨[M], 北京:科学出版社, 1980:225.
[19] 卢敬华. 西南低涡概论[M]. 北京:气象出版社,1986:263.
[20] 丁一汇. 天气动力学中的诊断分析方法[M]. 北京:科学出版社, 1989:293.
[21] 全美兰,刘海文,朱玉祥,等. 高空急流在北京“7.21”暴雨中的动力作用[J]. 气象学报, 2013, 71(6):1012-1019.
[22] Uccellini L W, Johnson D R. The Coupling of Upper and Lower Tropospheric Jet Streaks and Implications for the Development of Severe Convective Storms[J]. Mon.wea.rev, 1979, 107,682-703.
[23] 刘还珠,张绍晴.湿位涡与锋面强降水天气的三维结构[J].应用气象学报,1996,7(3):275-284.
[24] 丁一汇,胡国权.1998年中国大洪水时期的水汽收支研究[J].气象学报,2003,61(2):129-145.
[25] Huang Y, Cui X.Moisture sources of torrential rainfall events in the Sichuan Basin of China during summers of 2009-2013[J]. Journal of Hydrometeorology, 2015,16:1906-1917.

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备注/Memo

收稿日期:2015-09-22 基金项目:重庆市气象局开放式研究基金资助项目(KFJJ-201102)

更新日期/Last Update: 2016-02-28