PDF下载分享

[1]贺芸萍,谌芸,肖天贵.“5·22”广州西北气流控制下特大暴雨过程的中尺度特征分析[J].成都信息工程大学学报,2023,38(04):440-449.[doi:10.16836/j.cnki.jcuit.2023.04.011]
　HE Yunping,CHEN Yun,XIAO Tiangui.Analysis of the Mesoscale Characteristics of the Heavy Rain Process Controlled by the Northwest Airflow in Guangzhou on “5·22”[J].Journal of Chengdu University of Information Technology,2023,38(04):440-449.[doi:10.16836/j.cnki.jcuit.2023.04.011]

点击复制

“5·22”广州西北气流控制下特大暴雨过程的中尺度特征分析

成都信息工程大学学报[ISSN:1006-6977/CN:61-1281/TN] 卷: 38 期数: 2023年04期页码: 440-449 栏目: 大气科学出版日期: 2023-07-10

Title:: Analysis of the Mesoscale Characteristics of the Heavy Rain Process Controlled by the Northwest Airflow in Guangzhou on “5·22”

文章编号:: 2096-1618(2023)04-0440-10

作者:: 贺芸萍¹; 谌芸¹; 2; 3; 肖天贵¹; (1.成都信息工程大学大气科学学院, 四川成都 610225; 2.国家气象中心, 北京 100081; 3.南方海洋科学与工程广东省实验室(珠海), 广东珠海 519082)

Author(s):: HE Yunping¹; CHEN Yun¹; 2; 3; XIAO Tiangui¹; (1.College of Atmospheric Sciences, Chengdu University of Information Technology, Chengdu, 610225, China; 2.National Meteorological Center, CMA, Beijing, 100081, China; 3.Southern Marine Science and Engineering Guangdong Laboratory(Zhuhai), Zhuhai, 519082, China)

关键词:: 华南前汛期暴雨; 中尺度特征; 槽后西北气流; 地面中尺度辐合线; 列车效应

Keywords:: heavy rain in the pre-flood season in South China; mesoscale characteristics; northwest airflow after the trough; ground mesoscale convergence line; train effect

分类号:: P438

DOI:: 10.16836/j.cnki.jcuit.2023.04.011

文献标志码:: A

摘要:: 为提高对西北气流控制下暴雨过程的认识, 以期为此类暴雨预报提供支撑, 利用国家级自动站与区域加密自动站逐小时降水资料, FY-2G卫星和广州多普勒天气雷达探测等资料, 采用中尺度分析技术与重要物理量参数计算等方法, 分析“5·22”广州特大暴雨过程的中尺度特征。结果表明:降水主要发生在夜间至凌晨, 短时强降水占日雨量的比均达75%, 强对流性明显。暴雨过程由在西北气流控制下的下滑槽配合对流层低层的西南低空急流及其左侧南移进入广东的深厚低涡切变系统产生, 中高层西北气流与低层暖平流形成上干冷、下暖湿的不稳定层结。在高温高湿环境下东北风与西南风形成的地面辐合线触发对流, 夜间随着低空急流增强, 地面辐合增幅, 上升运动加剧。β中尺度对流云团合并加强, 后向传播的对流单体在西北气流引导下形成列车效应, 伴随着高降水效率的热带低质心暖云降水, 导致珠三角强降水产生并持续, 从而形成特大暴雨。

Abstract:: In order to improve the understanding of the rainstorm process under the control of the northwest airflow and provide support for such rainstorm forecast, this paper uses the hourly precipitation data of national automatic stations and regional encrypted automatic stations, FY-2G satellite data and Guangzhou Doppler weather radar detection data, etc., by methods of the mesoscale analysis technology and the calculation of important physical parameters to analyze the mesoscale characteristics of the “5·22” Guangzhou torrential rain process. The results show that: The precipitation in this rainstorm process mainly occurred from night to early morning, and the proportion of short-term heavy precipitation accounted for 75% of the daily rainfall, and the strong convection was obvious. The heavy rain process was caused by the down-slope trough controlled by the northwesterly air current, the southwest low-level jet in the lower troposphere and the deep low vortex shear system that moved southward from the left side into Guangdong. The unstable stratification of dry and cold upper layer and warm and humid lower layer is formed by the northwest airflow in the middle and upper layers and the warm advection in the lower layer. In the high-temperature and high-humidity environment, the ground convergence line formed by the northeasterly wind and the southwesterly wind triggered the convection. At night, with the strengthening of the low-level jet, the ground convergence increased and the upward movement was intensified. The β mesoscale convective cloud clusters merged and strengthened, and the backward propagating convective cells formed a train effect under the guidance of the northwest airflow. The train effect, accompanied by the tropical low-mass warm cloud precipitation with high precipitation efficiency, led to the occurrence and maintenance of heavy precipitation in the Pearl River Delta, and finally an extremely large rainstorm was formed.

参考文献/References:

[1] 鹿世瑾.华南气候[M].北京:气象出版社, 1990.
[2] 薛纪善.1994年华南夏季特大暴雨研究[M].北京:气象出版社, 1999.
[3] 黄士松.华南前汛期暴雨[M].广州:广东科技出版社, 1986:244.
[4] 臧传花, 李淑玲.逐步消空法预报西北气流条件下的山区暴雨[J].气象, 2005, 31(8):42-45.
[5] 郑婧, 许爱华, 孙素琴, 等.高空西北气流下特大暴雨的预报误差分析及思考[J].气象, 2018, 44(1):14.
[6] 赖绍钧, 何芬, 陈海山, 等.华南前汛期一次致洪暴雨过程的中尺度结构特征[J].高原气象, 2012, 31(1):167-175.
[7] 李亚琴.一次华南静止锋上的中尺度对流系统触发暴雨过程分析[C].中国气象学会年会灾害天气研究与预报分会场.2010.
[8] 伍志方, 曾沁, 吴乃庚, 等.广州“5·7”高空槽后和“5·14”槽前大暴雨过程对比分析[J].气象, 2011, 37(7):838-846.
[9] 胡雅君, 张伟, 赵玉春, 等.“5·7”闽南沿海暖区特大暴雨中尺度特征分析[J].气象, 2020, 46(5):14.
[10] 丁一汇.中国暴雨理论的发展历程与重要进展[J].暴雨灾害, 2019, 38(5):12.
[11] 慕建利, 王建捷, 李泽椿.2005年6月华南特大连续性暴雨的环境条件和中尺度扰动分析[J].气象学报, 2008(3):437-451.
[12] Akiyama T.A medium-scale cloud cluster in a Baiu front.Part I:Evolution process and a fine structure[J].J Meteor Sor Japan.1984, 62:485-504.
[13] Chen G T J.Mesoscale features observed in the Taiwan Mei-yu season[J].J Meteor Soc Japan, 1992, 70:497-515.
[14] 俞小鼎.短时强降水临近预报的思路与方法[J].暴雨灾害, 2013, 32(3):202-209.
[15] 张思嘉.一次广州特大暴雨事件的局地对流触发机制研究[D].南京:南京信息工程大学, 2019.
[16] 周兆丁, 陈芳丽, 曾丹丹, 等.广东前汛期一次锋前暖区暴雨触发机制分析[J].广东气象, 2019, 41(3):1-4.
[17] 李超, 陈潜, 赵春阳, 等.相似天气背景下深圳两次前汛期降水过程对比分析[J].海洋气象学报, 2021, 41(2):24-33.
[18] 叶朗明, 苗峻峰.华南一次典型回流暖区暴雨过程的中尺度分析[J].暴雨灾害, 2014, 33(4):342-350.
[19] 孙建华, 赵思雄.华南“94·6”特大暴雨的中尺度对流系统及其环境场研究Ⅰ.引发暴雨的β中尺度对流系统的数值模拟研究[J].大气科学, 2002(4):541-557.
[20] 傅慎明, 赵思雄, 孙建华, 等.一类低涡切变型华南前汛期致洪暴雨的分析研究[J].大气科学, 2010, 34(2):235-252.
[21] 张一平, 俞小鼎, 孙景兰, 等.一次槽后型大暴雨伴冰雹的形成机制和雷达观测分析[J].高原气象, 2014, 33(4):1093-1104.
[22] 曾智琳, 谌芸, 朱克云, 等.2017年“5.7”广州特大暴雨的中尺度特征分析与成因初探[J].热带气象学报, 2018, 34(5):791-805.
[23] Cressman G P.An operational objective analysis system[J].Monthly Weather Review, 1959, 87(10):367-374.
[24] 张小玲, 周庆亮, 谌芸, 等.中尺度天气分析技术在强对流天气预报中的应用[C].全国灾害性天气预报技术研讨会.2009.
[25] 张小玲, 谌芸, 张涛.对流天气预报中的环境场条件分析[J].气象学报, 2012, 70(4):13.
[26] 张红梅, 张深涛, 连晨放.福建西南部一次特大暴雨过程的双偏振雷达特征分析[J].气象与环境科学, 2021, 44(2):16-24.

备注/Memo

收稿日期:2022-04-06
基金项目:国家自然科学基金资助项目(41930972、41975001、91937301)
通信作者:谌芸.Email:chenyun@cma.gov.cn

更新日期/Last Update: 2023-07-10