Multiscale Features and Triggering Mechanisms of the Warm-Sector Heavy Rainfall Accompanied by Warm Shear Along the Yangtze–Huaihe Coastal Regions

Yiping Yu, Ling Zhang, Liuxian Song, Wei Li, Lu Zhou, Ouyang Lin
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Abstract

Using high-resolution hourly precipitation data and ERA5 reanalysis data, this study employs the K-means method to categorize 32 cases of warm-sector heavy rainfall events accompanied by a warm-type shear line (WSWR) along the Yangtze–Huaihe coastal region (YHCR) from April to September during 2010–17. Considering the synoptic system features of WSWR by K means, the result reveals 15 southwest type (SW-type) and 17 south-biased type (S-type) WSWR events. Composite analysis illuminates the distinct dynamic and thermodynamic features of each type. For the SW-type WSWR, the maximum value of water vapor is concentrated around 850 hPa in the lower troposphere. The YHCR is located at the intersection of the exit area of the 850-hPa synoptic low-level jet (LLJ) and the entrance area of the 600-hPa jet. The suction effects, combined with the location of YHCR on the left side of the boundary layer jet (BLJ), facilitate the triggering of local convection. Conversely, the S-type WSWR shows peak water vapor in the boundary layer. Before the onset of WSWR events, a warm, humid tongue indicated by pseudoequivalent potential temperature θse is present in the boundary layer, signified by substantial unstable energy. The BLJ aids mesoscale ascent on its terminus, enhancing convergence along the coastline. The BLJ also channels unstable energy and water vapor to the YHCR, causing significant rainfall. Typical case studies of both types show similar environmental backgrounds. The scale analysis shows mesoscales of dynamic field are crucial in shaping both types of WSWR, while the large-scale and meso-α-scale dynamic field facilitate the transportation of moist and warm airflow.
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长江-淮河沿岸暖切变伴随暖扇面强降雨的多尺度特征及触发机制
本研究利用高分辨率小时降水资料和ERA5再分析资料,采用K均值法对2010-17年4-9月长江-淮河沿岸地区伴有暖型切变线(WSWR)的32例暖扇区暴雨事件进行了分类。通过K方法分析暖型切变线的天气系统特征,结果表明暖型切变线的西南型(SW型)和偏南型(S型)暴雨事件分别为15次和17次。综合分析揭示了每种类型独特的动力和热动力特征。对于 SW 型 WSWR,水汽的最大值集中在对流层低层 850 hPa 附近。YHCR 位于 850 hPa 同步低空喷流出口区域和 600 hPa 喷射入口区域的交汇处。吸力效应加上 YHCR 位于边界层喷流(BLJ)的左侧,有利于引发局地对流。相反,S 型 WSWR 则显示出边界层的水汽峰值。在 WSWR 事件开始之前,边界层中会出现伪等势温 θse 所示的暖湿舌,标志着大量的不稳定能量。BLJ 在其终点帮助中尺度上升,加强了沿海岸线的辐合。BLJ 还将不稳定能量和水汽输送到 YHCR,造成大量降雨。两种类型的典型案例研究显示了相似的环境背景。尺度分析表明,中尺度动力场对形成这两种类型的 WSWR 起着关键作用,而大尺度和中α尺度动力场则促进了湿暖气流的输送。
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