| 267 | 0 | 16 |
| 下载次数 | 被引频次 | 阅读次数 |
【目的】全球气候变化的背景下,气候变率陡增,极端事件频发,对人民生命财产和社会经济健康发展带来巨大威胁。2021年安徽省梅雨期平均降雨量317 mm,较常年同期偏丰近三成。为分析暴雨水汽输送场,揭示其发展过程特征。【方法】基于拉格朗日混合单粒子轨迹模型(HYSPLIT)计算了2021年7月合肥市董铺、大房郢水库流域场次降雨期间水汽输送轨迹。【结果】结果显示:降雨量空间分布不均匀,平均降雨量为306.6 mm,刘庙站的降雨量最高(356.5 mm),而最低的是沈油坊站(228.5 mm);不同高度层的水汽输送轨迹特征存在差异,925 hPa有西太平洋的东南路径、孟加拉湾的西南路径、中国南海的南向路径,对应的水汽贡献率分别为44.4%、43.8%、11.8%;850 hPa有西太平洋路径和孟加拉湾路径,分别为26.3%、73.7%;700 hPa有西太平洋路径、印度洋的西南路径、青藏高原的西向路径,分别为17.1%、77.9%、5.0%;随着水汽轨迹模拟的初始高度增加,水汽轨迹数目的空间分布表现为西多东少,且温度和比湿度在输送过程中均发生了增加(减少)。【结论】2021年7月合肥市董铺、大房郢水库流域场次降雨在不同高度层上的水汽均主要来源于海洋通道,尤其是来自西太平洋、孟加拉湾和印度洋的水汽贡献为主。而在850 hPa高度层上,出现了非常强烈的水汽辐合带,为局部短时强降雨供应着充沛的水汽。
Abstract:[Objective]In the context of global climate change, climate variability has increased sharply, and extreme events have become more frequent, posing significant threats to people's lives, property, and the healthy development of the socio-economic system. During the 2021 Meiyu season in Anhui Province, the average rainfall was 317 mm, which was nearly 30% higher than the long-term average. To analyze the moisture transport field of heavy rainfall and reveal its development characteristics, [Methods]the Lagrangian Hybrid Single Particle Trajectory Model(HYSPLIT) was utilized to simulate the moisture transport trajectories during the rainfall event in the Dongpu and Dafangying reservoir basins of Hefei City in July 2021.[Results]The result indicate that the spatial distribution of rainfall was uneven, with an average rainfall of 306.6 mm. The highest rainfall was recorded at Liumiao Station(356.5 mm), while the lowest was at Shenyoufang Station(228.5 mm). The characteristics of moisture transport trajectories varied at different height levels. At 925 hPa, there were southeast paths from the Western Pacific, southwest paths from the Bay of Bengal, and southward paths from the South China Sea, with corresponding moisture contribution rates of 44.4%, 43.8%, and 11.8%, respectively. At 850 hPa, the paths from the Western Pacific and the Bay of Bengal accounted for 26.3% and 73.7%, respectively. At 700 hPa, the paths included the Western Pacific, southwest paths from the Indian Ocean, and westward paths from the Tibetan Plateau, with contributions of 17.1%, 77.9%, and 5.0%, respectively. As the initial height of the moisture trajectory simulation increased, the spatial distribution of the number of trajectories showed a pattern of more in the west and less in the east, and both temperature and specific humidity increased(decreased) during the transport process.[Conclusion]The moisture for the rainfall event in the Dongpu and Dafangying reservoir basins of Hefei City in July 2021 primarily originated from oceanic channels at different height levels, with significant contributions from the Western Pacific, the Bay of Bengal, and the Indian Ocean. At the 850 hPa level, a very strong moisture convergence zone was observed, providing ample moisture for localized heavy rainfall.
[1] ZHANG W,ZHOU T,WU P.Anthropogenic amplification of precipitation variability over the past century [J].Science,2024,385(6707):427-432.
[2] 郑芳,李芳然,甘义群,等.极端气候事件对洞庭湖水文连通性变化的影响[J].南水北调与水利科技(中英文),2024,22(1):67-79.ZHENG F,LI F R,GAN Y Q,et al.The impact of extreme climatic events on hydrological connectivity of Dongting Lake[J].South-to-North Water Transfers and Water Science & Technology,2024,22(1):67-79.
[3] CHIAPPA J,PARSONS D B,FURTADO J C,et al.Short-duration extreme rainfall events in the central and eastern United States during the summer:2003-2023 trends and variability [J].Geophysical Research Letters,2024,51(17):e2024GL110424.
[4] 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):395-406.DING Yihui.The major advances and development process of the theory of heavy rainfalls in China [J].Torrential Rain and Disasters,2019,38(5):395-406.
[5] 廖晓农,倪允琪,何娜,等.导致“7.21”特大暴雨过程中水汽异常充沛的天气尺度动力过程分析研究[J].气象学报,2013,71(6):997-1011.LIAO Xiaonong,NI Yunqi,HE Na,Song Qiaoyun.Analysis of the synopticscale dynamic process causing the extreme moisture environment in the“7.21”heavy rain case [J].Acta Meteorologica Sinica,2013,71(6):997-1011.
[6] 张芳丽,李国平,李武阶.2020年7月5—6日武汉江夏特大暴雨水汽源地和输送特征分析[J].暴雨灾害,2022,41(4):375-383.ZHANG Fangli,LI Guoping,LI Wujie.Analyses of moisture sources and transport characteristics in a rainstorm event in Jiangxia,Wuhan during July 5—6,2020 [J].Torrential Rain and Disasters,2022,41(4):375-383.
[7] 陈小婷,赵强,刘慧,等.黄土高原两次不同类型暴雨水汽特征分析[J].干旱气象,2022,40(6):968-980.CHEN Xiaoting,ZHAO Qiang,LIU Hui,et al.Analysis of water vapor characteristics of two different types of rainstorms over the Loess Plateau [J].Journal of Arid Meteorology,2022,40(6):968-980.
[8] 施逸,江志红,李肇新.基于拉格朗日方法的中国东部雨季水汽输送垂直特征[J].大气科学,2022,46(2):380-392.SHI Yi,JIANG Zhihong,LI Laurent.Vertical characteristics of water vapor transport during the rainy season in eastern China based on the Lagrangian method [J].Chinese Journal of Atmospheric Sciences,2022,46(2):380-392.
[9] 杨玮,徐敏,周顺武,等.江淮流域6—7月极端强降水事件时空变化及环流异常[J].高原气象,2017,36(3):718-735.YANG W,XU M,ZHOU S W,et al.Spatial-temporal variation of extreme precipitation events from June to July over Yangtze-Huaihe River Basin and the circulation anomalies [J].Plateau Meteorology,2017,36(3):718-735.
[10] 马潇祎,范可,杨洪卿.2021年盛夏中国东部极端降水月际演变成因及可预测性[J].大气科学学报,2024,47(4):541-556.MA X Y,FAN K,YANG H Q.Causes and predictability of the inter-month evolution of extreme precipitation over eastern China in midsummer 2021 [J].Transactions of Atmospheric Sciences,2024,47(4):541-556.
[11] 黄军.多目标条件下安徽省江淮分水岭重点流域水量分配方案研究[J].水利发展研究,2023,23(9):49-55.HUANG Jun.Research on water allocation scheme for key basins of the JianghuaiWater Divide in Anhui Province under multi-target conditions[J].Water Resources Development Research,2023,23(9):49-55.
[12] WANG Y,PENG Z,WU H,et al.Spatiotemporal variability in precipitation extremes in the Jianghuai Region of China and the analysis of its circulation features [J].Sustainability,2022,14:6680.
[13] CHEN Y,LIU B,LUO Y,et al.Relative contribution of moisture transport during TC active and inactive periods to the precipitation in Henan Province of North China:Mean state and an extreme event [J].Journal of Climate.2023,36(11):3611-3623.
[14] CHEN Y,ZHANG S,GONG G,et al.Impacts of moisture transport on extreme precipitation in the Central Plains Urban Agglomeration,China [J].Global and Planetary Change,2024,242(3-4):104582.
[15] GUAN Y,GU X,SLATER L J,et al.Tracing anomalies in moisture recycling and transport to two record-breaking droughts over the Mid-to-Lower Reaches of the Yangtze River [J].Journal of Hydrology,2022,609:127787.
[16] DRAXLER R,HESS G.An overview of the HYSPLIT_4 modeling system for trajectories,dispersion,and deposition [J].Australian Meteorological Magazine,1998,47:295-308.
[17] DRAXLER R,HESS G.Description of the HYSPLIT_4 modelling system [R].Silver Spring:Air Resources Laboratory,1997.
[18] 周晓霞,丁一汇,王盘兴.夏季亚洲季风区的水汽输送及其对中国降水的影响[J].气象学报,2008,66 (1):59-70.ZHOU Xiaoxia,DING Yihui,WANG Panxing.Moisture transpotr in Asian summer monsoon region and its relationship with summer precipitation in China [J].Acta Meteorologica Sinica,2008,66 (1):59-70.
[19] WANG N,XINMIN Z,ZHENG Y,et al.The atmospheric moisture residence time and reference time for moisture tracking over China [J].J Hydrometeorol,2018,19(7):1131-1147.
[20] 江志红,任伟,刘征宇,等.基于拉格朗日方法的江淮梅雨水汽输送特征分析[J].气象学报,2013,71(2):295-304.JIANG Zhihong,REN Wei,LIU Zhengyu,et al.Analysis of water vapor transport characteristics during the Meiyu over the Yangtze-Huaihe River valley using the Lagrangian method [J].Acta Meteorologica Sinica,2013,71(2):295-304.
[21] 丁一汇.高等天气学[M].北京:气象出版社,2005.DING Yihui.Advanced Synoptic Meteorology[M].Beijing:China Meteorological Press,2005.
[22] CHEN Y,LUO Y.Analysis of paths and sources of moisture for the South China rainfall during the presummer rainy season of 1979—2014 [J].Journal of Meteorological Research,2018,32:744-757.
[23] XU X,ZHAO T,LU C,et al.An important mechanism sustaining the atmospheric “water tower” over the Tibetan Plateau [J].Atmospheric Chemistry and Physics,2014,14(20):11287-11295.
[24] SUN B,ZHU Y L,WANG H.The recent interdecadal and interannual variation of water vapor transport over Eastern China [J].Advances in Atmospheric Sciences,2011,28(5):1039-1048.
[25] 甘贝贝,刘梅冰.1962—2021 年闽江流域干湿演变特征及其对 ENSO 事件的响应[J].南水北调与水利科技(中英文),2024,22(3):545-556.GAN B B,LIU M B.Dry-wet evolution characteristics and response to ENSO events in the Minjiang River basin from 1962 to 2021[J].South-to-North Water Transfers and Water Science & Technology,2024,22(3):545-556.
[26] YANG K,LIU C,CAI J,et al.The north-south shift of the ridge location of the western Pacific subtropical high and its influence on the July precipitation in the Jianghuai region from 1978 to 2021 [J].Frontiers in Earth Science,2023,11:1251294.
[27] NIE Y,SUN J.Moisture sources and transport for extreme precipitation over Henan in July 2021 [J].Geophysical Research Letters,2022,49(4):e2021GL097446.
[28] 庄晓翠,李博渊,赵江伟,等.基于HYSPLIT模式分析的塔克拉玛干沙漠南缘暴雨水汽特征[J].气象,2022,48(3):311-323.ZHUANG X C,LI B Y,ZHAO J W,et al.Water vapor characteristics of rainstorm in southern Taklimakan Desert based on HYSPLrT model analysis [J].Meteorological Monthly,2022,48(3):311-323.
[29] 杨浩,江志红,刘征宇,等.基于拉格朗日法的水汽输送气候特征分析:江淮梅雨和淮北雨季的对比[J].大气科学,2014,38(5):965-973.YANG H,JIANG Z H,LIU ZHENG Y,et al.Analysis of climatic characteristics of water vapor transport based on the Lagrangian method:A comparison between Meiyu in the Yangtze-Huaihe river region and the Huaibei rainy season [J].Chinese Journalof Atmospheric Sciences,2014,38(5):965-973.
[30] ZHANG L,ZHAO D,ZHOU T,et al.Moisture origins and transport processes for the 2020 Yangtze River Valley record-breaking Mei-yu rainfall [J].Advances in Atmospheric Sciences,2021,38(6):1-12.
[31] WANG L,XIHUI G,SLATER L,et al.Attribution of the record-breaking extreme precipitation events in July 2021 over Central and Eastern China to anthropogenic climate change [J].Earth’s Future,2023,11(9):e2023EF003613.
基本信息:
DOI:10.13928/j.cnki.wrahe.2025.11.004
中图分类号:P426.62
引用信息:
[1]陈镜元,刘晓东,郭园,等.合肥市21·7暴雨水汽输送过程与特征解析[J].水利水电技术(中英文),2025,56(11):48-58.DOI:10.13928/j.cnki.wrahe.2025.11.004.
基金信息:
国家自然科学基金项目(42377346); 陕西省自然科学基础研究计划联合基金项目(2022JC-LHJJ-01)