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气象:2014,40(1):48-58
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2012年早春河南一次高架雷暴天气成因分析
(1.河南省农业气象保障与应用技术重点实验室,郑州 450003;2.河南省气象台,郑州 450003;3.中国气象局气象干部培训学院,北京 100081;4.河南省气象局,郑州 450003)
Analysis on Weather Causes of an Elevated Thunderstorm in Henan in Early Spring 2012
(1.Henan Key Laboratory of Agrometeorological Ensuring and Applied Technique, Zhengzhou 450003;2.Henan Meteorological Observatory, Zhengzhou 450003;3.China Meteorological Administration Training Centre, Beijing 100081;4.Henan Meteorological Bureau, Zhengzhou 450003)
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投稿时间:2012-12-28    修订日期:2013-07-10
中文摘要: 利用常规观测、新一代天气雷达、雷电定位监测和1°×1° NCEP分析资料对2012年早春河南一次伴有多种天气现象的高架雷暴(elevated convection)成因进行了天气学分析,建立了高架雷暴天气的流型配置模型。结果表明:(1)本次高架雷暴发生在中纬度暖性低槽发展东移的环流形势下,边界层顶以上近中性条件不稳定性层结(偏向于很弱的条件不稳定)在高空槽前正涡度平流和低层暖湿平流的强迫作用下,使得700 hPa以上出现较大范围的较强上升运动,地面冷高压后部偏东气流对高架对流的产生具有冷垫作用。(2)出现高架雷暴的大气低层存在较强的逆温层,700 hPa暖温度脊前的西南暖湿低空急流为高架雷暴的产生提供了充足的水汽和能量,并使低层逆温层顶以上出现弱条件不稳定层结和较高的露点,两者结合导致弱的最不稳定对流有效位能MUCAPE,其值在10~50 J·kg-1之间,高架对流是由逆温层顶附近及其以上的暖湿气块被抬升而造成的,对应1.0~3.0 m·s-1的雷暴内最大上升气流。(3)此次高架雷暴发生在强斜压环境中,有较强的动力不稳定,中低层0~6 km和0~3 km垂直风切变值分别为(3.0~3.7)×10-3和(5.0~5.3)×10-3 s-1。(4)本次过程-10℃、-20℃ 层高度分别在5、6.5 km,弱对流云顶高度多在6~8 km或以上,超过了冻结层高度,易导致雷电发生。(5)从流型配置模型看,高空暖性低槽、中高层强烈发展的温度脊、700 hPa强西南暖湿低空急流和边界层冷中心、冷温度槽、地面冷高压等是值得关注的影响系统,当这些天气系统有利配置时,应注意低层逆温层、中层弱条件不稳定层结的建立以及高架雷暴发生的可能性。
Abstract:The conventional observation, new generation weather radar, lightning locating monitoring and NCEP 1°×1° analysis data are used to analyze the synoptic causes of the elevated thunderstorm in early spring of 2012 that was accompanied by a variety of weather phenomena and a flow configuration model of the elevated thunderstorm is established. The results showed that: (1) the elevated thunderstorm occurs in the circulation situation of warm trough moving eastward and developing in middle latitudes. The near neutral conditions instability stratification above the top of the boundary layer (biased in favor of weak conditional instability), which is in the forcing effect of positive vorticity advection in front of trough and warm and wet advection at low levels, makes a larger range of strong upward motion above 700 hPa so that easterly winds in the rear of surface cold high has a role of cooling cushion on the production of the elevated convection. (2) There is a strong inverse temperature layer in the lower atmosphere where elevated thunderstorm exists. The warm and wet southwest low level jet in front of temperature ridge at 700 hPa provides ample moisture and energy for production of an elevated thunderstorm, causing weak conditions with unstable stratification and higher dew point above the top of low level temperature inversion. The combination of the two leads to the weak and most unstable convective available potential energy MUCAPE, whose value is between 10 and 50 J·kg-1. The elevated convection is caused by uplift of warm and wet block near and above the top of the inversion layer, corresponding to 1.0-3.0 m·s-1 maximum updrafts within thunderstorms. (3) The elevated thunderstorm occurs in strong baroclinic environment, where there is a strong dynamic instability, in the lower level 0-6 km and 0-3 km vertical wind shear values are (3.0-3.7)×10-3 s-1 and (5.0-5.3)×10-3 s-1 respectiveny. (4) The -10℃ and -20℃ layers in this process are respectively in the height of 5 km and 6.5 km, and the height of weak convective cloud top is more in the 6-8 km or above, exceeding the height of the freezing level and easily leading to the occurence of lightning. (5) From the flow configuration model, warm trough at high altitude, the strongly developed temperature ridge at middle and high layer, the warm and wet southwest low level jet at 700 hPa and cold boundary center, cold temperature trough, surface cold high pressure etc., make up a noteworthy affecting system. When these weather systems are favorable for configuration, the low level temperature inversion, the establishment of weak condition unstable stratification at middle layer and the likelihood of elevated thunderstorms should be concerned.
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基金项目:中国气象局关键技术集成项目(CMAGJ2012M31)、河南省科技厅项目(112102310033)和河南省气象局项目(Z201201)共同资助
引用文本:
张一平,俞小鼎,孙景兰,梁俊平,吕林宜,2014.2012年早春河南一次高架雷暴天气成因分析[J].气象,40(1):48-58.
ZHANG Yiping,YU Xiaoding,SUN Jinglan,LIANG Junping,Lv Linyi,2014.Analysis on Weather Causes of an Elevated Thunderstorm in Henan in Early Spring 2012[J].Meteor Mon,40(1):48-58.