Characteristics of mesoscale convective systems and related precipitation in the three-river-source region of China

IF 2.3 4区地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES

Meteorological Applications Pub Date : 2024-04-25 DOI:10.1002/met.2181

Qiyu Xie, Xiuping Yao

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Abstract

Mesoscale convective systems (MCSs) are important air water sources to the Three-river-source (TRS) region known as the “Chinese water tower.” Using hourly equivalent blackbody temperature (T_BB) data from geostationary satellites of Chinese Fengyun-2 series during the warm season (May–August) in 2005–2020 and an objective algorithm, MCSs in the TRS are divided into meso-α (M_αCS), meso-β (M_βCS), and meso-γ (M_γCS), and M_αCS and M_βCS are subdivided into larger meso-α (LM_αCS), smaller meso-α (SM_αCS), larger meso-β (LM_βCS), and smaller meso-β (SM_βCS). Results show that a high-frequency zone of MCSs in the TRS distributes along the source of the rivers. Most MCSs, except LM_αCS, develop and dissipate in situ. The interannual variation in MCS frequency exhibits a decreasing trend, especially after 2013, mainly due to the decrease in MCSs in the source region of the Yellow–Lancang River. The occurrence of MCSs peaks in August, but MCSs are most likely to produce precipitation in July and usually generate between 1600–2200 h LST (UTC + 8). The precipitation caused by MCSs to the total precipitation (precipitation ratio, PR) accounts for about 40%; MCS PR is closely related to, and increases with, the horizontal scale of the MCS, with M_αCS PR being the highest, exceeding 67%. The contribution of MCSs to precipitation is mainly reflected in weak precipitation, smaller than 10.0 mm/h. Most of the maximum precipitation of MCSs appears after MCSs reach their prime, with the maximum lag by M_αCS up to 2 h.

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中国三江源地区中尺度对流系统及相关降水的特征

中尺度对流系统（MCS）是被称为 "中华水塔 "的三江源地区的重要空气水源。利用中国风云二号静止轨道卫星提供的 2005-2020 年暖季（5-8 月）每小时等效黑体温度（TBB）数据和一种客观算法、TRS中的MCS分为中层α（MαCS）、中层β（MβCS）和中层γ（MγCS），MαCS和MβCS又分为大中层α（LMαCS）、小中层α（SMαCS）、大中层β（LMβCS）和小中层β（SMβCS）。结果表明，在 TRS 中，沿河流源头分布着一个高频中尺度地震带。除 LMαCS 外，大多数 MCS 都是在原地发展和消散的。MCS频率的年际变化呈下降趋势，尤其是在2013年之后，这主要是由于黄河-澜沧江源区MCS的减少。多场静稳事件发生的高峰期在 8 月，但多场静稳事件最有可能在 7 月产生降水，通常发生在 1600-2200 h LST（UTC + 8）之间。MCS引起的降水量占总降水量的比例（降水比，PR）约为40%；MCS的PR与MCS的水平尺度密切相关，并随MCS水平尺度的增大而增大，其中MαCS的PR最大，超过67%。多变气流对降水的贡献主要体现在弱降水上，小于 10.0 毫米/小时。MCSs的最大降水量大多出现在MCSs达到盛期之后，MαCS的最大滞后时间长达2 h。

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来源期刊

Meteorological Applications 地学-气象与大气科学

CiteScore

5.70

自引率

3.70%

发文量

审稿时长

>12 weeks

期刊介绍： The aim of Meteorological Applications is to serve the needs of applied meteorologists, forecasters and users of meteorological services by publishing papers on all aspects of meteorological science, including: applications of meteorological, climatological, analytical and forecasting data, and their socio-economic benefits; forecasting, warning and service delivery techniques and methods; weather hazards, their analysis and prediction; performance, verification and value of numerical models and forecasting services; practical applications of ocean and climate models; education and training.