南疆西部春季一次极端暴雪天气综合分析

doi:10.12118/j.issn.1000–6060.2021.110

摘要/Abstract

摘要：

利用FY2E卫星资料,多普勒天气雷达产品,常规高空及地面观测数据和美国气象环境预报中心（NCEP,0.25°×0.25°）再分析资料,对2017年3月3—6日南疆西部一场极端暴雪过程进行综合分析。结果表明：500 hPa中亚低涡是此次极端暴雪天气的影响系统。暴雪的水汽主要有3支输送路径,分别是中高层的偏西、偏南和中低层的偏东路径。本次降雪具有冷季高架对流的部分特征：南疆盆地850~700 hPa冷空气东灌形成的偏东急流将南疆西部相对暖湿的空气抬升到一定高度,起到“冷垫”的作用;在卫星云图上,降雪云带内有黑体亮温（TBB）<-65 ℃、尺度介于80~200 km之间的中-β尺度对流云团;雷达回波表现为层状回波中夹杂有块状回波,最大反射率>40 dBZ,回波顶高>6 km;进一步分析地转绝对动量（Mg）和假相当位温（θse）发现,条件性对称不稳定导致的倾斜对流导致强降雪发生。

关键词: 暴雪, 低空急流, 不稳定机制, 倾斜对流, 南疆西部

Abstract:

Based on the high radiosonde observation data, National ground weather station observation data, National Center for Environmental Prediction (NCEP, 0.25°×0.25°) reanalysis data, FY2E satellite data, and products of Kashgar Doppler weather radar station, extreme snowstorm weather in the west of southern Xinjiang of China from March 3 to 6, 2017 was comprehensively analyzed. According to the findings, the 500 hPa low vortex cutoff in Central Asia is the primary influence system of the extreme snowstorm. In this snowstorm, three main branches of water vapor emerge from the west and south of the middle and high layers, as well as from the east of the middle and low layers. The long-term maintenance of east jet formed between 850-700 hPa is not only critical in water vapor transportation (the water vapor transports from the eastern part of Tarim Basin in southern Xinjiang to the west and converges in the west of southern Xinjiang forming a convergence center, increasing the efficiency of water vapor convergence), but it also lifts the relatively warm and humid air in the west of southern Xinjiang to a certain height and acts as a “cold pad”. In this snowfall process, the development and maintenance of meso-β scale convective cloud clusters with black body temperature (TBB) <-65 °C and scales between 80-200 km in the cloud belt are the main reasons for the high snowfall intensity. Kashgar station’s Doppler radar echo appears to be a mixed echo accompanied by stratiform and block cloud echo. The reflectivity factor of stratiform cloud echo is typically 15-25 dBZ, with a large horizontal scale, long time duration, and a small variation range, resulting in long-term stable snowfall. The strongest reflectivity factor of block echo is >40 dBZ, and the top height is >5 km, indicating convective echo characteristics, resulting in strong hourly snow over 2 mm·h^-1. Further study shows that the extreme snowstorm process shows part of the characteristics of elevated convection in the cold season. The latitude-altitude profiles of geostrophic absolute momentum (Mg) and pseudo equivalent potential temperature (θse), together with the Wuqia station, the largest snowfall center, show that during the snowstorm process, the slope of θse is greater than that of Mg between 700-550 hPa, satisfying the conditional symmetric instability criterion. It is preliminarily judged that the extreme snowfall is caused by the inclined convection caused by the conditional symmetric instability.

Key words: snowstorm, low level jet, instability mechanism, oblique convection, the west of southern Xinjiang

施俊杰,孙鸣婧,吕新生,张俊兰,李火青. 南疆西部春季一次极端暴雪天气综合分析[J]. 干旱区地理, 2022, 45(1): 131-140.

SHI Junjie,SUN Mingjing,LYU Xinsheng,ZHANG Junlan,LI Huoqing. Comprehensively analysis of an extreme snowstorm in the west of southern Xinjiang in spring[J]. Arid Land Geography, 2022, 45(1): 131-140.

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