An Extreme Monsoonal Heavy Rainfall Event over Inland South China in June 2023: A Synoptic Causes Analysis

An extreme monsoonal heavy rainfall event lasted for nine days and recurred in the interior of northern south China from June 13 to 21, 2022. Using regional meteorological stations and ERA5 reanalysis data, the causes of this extreme monsoonal rainfall event in south China were analyzed and diagnosed. The results are shown as follows. A dominant South Asian high tended to be stable near the Qinghai-Tibet Plateau, providing favorable upper-level dispersion conditions for the occurrence of heavy rainfall in south China. A western Pacific subtropical high dominated the eastern part of the South China Sea, favoring stronger and more northward transport of water vapor to the northern part of south China at lower latitudes than normal. The continuous heavy precipitation event can be divided into two stages. The first stage (June 13-15) was the frontal heavy rainfall caused by cold air (brought by an East Asian trough) from the mid-latitudes that converged with a monsoonal airflow. The heavy rains occurred mostly in the area near a shear in front of the center of a synoptic-system-related low-level jet (SLLJ), and the jet stream and precipitation were strongest in the daytime. The second stage (June 16-21) was the warm-sector heavy rainfall caused by a South China Sea monsoonal low-level jet penetrating inland. The heavy rainfall occurred on the windward slope of the Nanling Mountains and in the northern part of a boundary layer jet (BLJ). The BLJ experienced five nighttime enhancements, corresponding well with the enhancement of the rainfall center, showing significant nighttime heavy rainfall characteristics. Finally, a conceptual diagram of inland-type warm-sector heavy rainfall in south China is summarized.     

2013—2017年夏季东北冷涡下东北地区MCS的统计特征

利用2013—2017年6—8月FY-2E和FY-2G地球静止卫星相当黑体温度（Black Body Temperature,TBB）资料、NCEP/NCAR再分析资料,对我国夏季东北冷涡下东北地区MCS的分布和活动特征进行了统计分析,结果表明：（1） MCS的活动具有明显的月际变化和日变化特征,6月对流活动最活跃。MCS的主要移向是东、东北和东南,平均移动距离3.99个经纬距。（2） MCS成熟时刻的面积、偏心率和生命史均小于江淮地区以及中国中东部,云顶高度低于江淮地区,整个生命史表现出发展快消亡慢的特征,与江淮地区相反。（3）基于MCS的定义得到的Z标准,对2016—2017年的MCS作了统计分析并与J标准统计得到的MCS进行对比,得出,两种定义下的MCS环境场特征基本一致,主要表现为MCS多生成于500 hPa槽前和槽后,对流层高层MCS位于双急流之间靠近北支急流的辐散区,南侧急流高度在200 hPa,北侧的急流高度在250 hPa。低层,位于低空急流左侧,低涡南侧、东南侧,有较强的水汽和动量输送。槽前生成的MCS南侧中层存在垂直反环流向MCS输送干暖空气与位涡,槽后生成的MCS两侧均有大值位涡向其输送,同时北侧冷干空气的输送使锋区及上升运动加强,更有利于MCS的形成。（4）两种标准下的MCS造成的降水明显不同,在统计强降水方面Z标准要优于J标准。由于Z标准空间与时间尺度较小,统计得到的MCS较多;但同时会遗漏部分相对弱的MCS。     

中国夏季主雨带的形成过程

我国夏季主雨带的形成，是从上一年夏季开始的，共经历3个阶段，（1）上一年5－9月副热带西风急流的孕育期，（2）10－3月西风急流发展期，（3）西风急流为西太平副热带高压替代期（本年5－9月）－主雨带形成，在3个阶段中，北半球大气加热场上制约西风急流变化的最活跃的因子，是高，中纬地区由流状低云和冰雪盖交替进行的冷却大气过程。     

钱塘江古海塘塘基防渗加固现场试验研究

目前仍然坚守在防洪御潮第一线的钱塘江明清古海塘,由于年代久远,部分塘段的塘趾部位存在流土现象,因此,选用合理且不破坏古海塘风貌的塘基防渗加固方案来保护古海塘十分必要。以浙江海宁某明清古海塘试验段为依托,通过现场试验,对比研究了4种塘基防渗加固保护方案,通过有限元分析、现场渗透试验、加固后开挖检验、施工期对古海塘的影响监测等手段,分析总结了各加固方案的优缺点,得到了机械适当改制后的“塘趾旋喷注浆”方案为优选方案的结论,研究成果对下一步钱塘江临江古海塘保护工程的塘基防渗加固方案选取具有重要参考价值。     

滨海地区深基坑支护出现的问题及对策

在滨海地区,由于位置的特殊性和场地回填材料的复杂,基坑支护工程也有其特殊性,往往具有在一般地区难以遇到的实际困难。结合工程实例,介绍了在滨海地区典型的基坑支护工程中极易出现的问题,并介绍了设计和施工过程中的处理措施。     

“尤特”特大暴雨过程的热力条件分析

1311号强台风尤特登陆后给广东带来持续性大范围强降水,对流降水特征十分显著。文章分析了"尤特"影响期间大尺度环流背景,重点讨论了此次持续性强降水过程中大气层结问题。发现低空急流向广东输送强的暖平流,是广东大气层结不稳定得以持续维持的根本原因。进一步分析发现,低空急流本身并不是"暖"的,当"尤特"趋向陆地时,陆地上的暖气团在"尤特"环流强迫下向南传播扩散,低空急流穿越这一暖区时温度升高才具备"暖"的特性。温度诊断方程结果进一步证实这一点。通过个例反查,在许多登陆后造成连续强降水的台风过程中均发现了这一特征。因此,台风登陆引起环境温度场的演变以及与低空急流的配置需引起业务预报上的重视。     

土体表面三维位移测试的新方法

采用双目立体视觉与数字图像相关相结合的新方法,对静载作用下湿喷桩复合地基室内模型的土体表面三维位移进行测试。给出了双目立体视觉系统的标定结果,提出了提取角点坐标的新方法及基于仿射变换的左右摄像机同名点的匹配搜索法,得到了土体表面三维位移随荷载变化的曲线。试验结果证明,将该系统应用于湿喷桩复合地基室内模型的土体表面位移测试是一种有益的尝试,也为土体位移测试提供了新的方法。     

Mesocosm experiments identifying hotspots of groundwater upwelling in a water column by fibre optic distributed temperature sensing

Lacustrine groundwater discharge (LGD) can substantially impact ecosystem characteristics and functions. Fibre optic distributed temperature sensing (FO‐DTS) has been successfully used to locate groundwater discharge into lakes and rivers at the sediment–water interface, but locating groundwater discharge would be easier if it could be detected from the more accessible water surface. So far, it is not clear if how and under which conditions the LGD signal propagates through the water column to the water surface–atmosphere interface, and what perturbations and signal losses occur along this pathway. In the present study, LGD was simulated in a mesocosm experiment. Under winter conditions, water with temperatures of 14 to 16 °C was discharged at the bottom of a 10 × 2.8‐m mesocosm. Water within this mesocosm ranged from 4.0 to 7.4 °C. Four layers (20, 40, 60, and 80 cm above the sediment) of the 82 cm deep mesocosm were equipped with FO‐DTS for tracing thermal patterns in the mesocosm. Aims are (a) to test whether the positive buoyancy of relatively warm groundwater imported by LGD into shallow water bodies allows detection of LGD at the lake's water surface–atmosphere interface by FO‐DTS, (b) to analyse the propagation of the temperature signal from the sediment‐water interface through the water column, and (c) to learn more about detectability of the signal under different discharge rates and weather conditions. The experiments supported the benchmarking of scale dependencies and robustness of FO‐DTS applications for measuring upwelling into aquatic environments and revealed that weather conditions can have important impacts on the detection of upwelling at water surface–atmosphere interfaces at larger scales.     

桂林市2005年6月连续性暴雨的季风扰动及动力条件分析

通过对2005年6月连续性暴雨过程发生前后的天气形势和物理量场进行分析,发现暴雨发生时,与500hPa螺旋度、涡度及850hPa水汽通量配置较好。暴雨前期低空急流加强,表现在暴雨发生前850hPa沿110°E有V分量的增长。另外,可通过对T 213物理量预报场的分析,判断未来暴雨发生的可能性。     

利用风廓线雷达研究郑州机场低空急流特征及其对飞行的影响

利用2016、2017年郑州机场高分辨率边界层风廓线雷达半小时平均观测资料, 对机场上空低空急流时空分布特征进行统计研究, 结果表明:夏末、秋季低空急流出现次数相对较少, 春季、夏初是高发时期, 冬季易出现较强的超低空急流, 只有春季风速从低层到高层呈现先增大后减小、再增大的变化过程, 8月末可能是急流的时空转换期; 夜间和凌晨是高发时段, 白天降低30%~40%, 一般情况下, 00—12时(世界时, 下同)急流较弱, 12时后明显增强向上发展, 19时开始减弱, 持续至21时; 急流中心最大风速一半以上在12~18 m/s, 高度集中在60~180 m和300~900 m, 超低空急流占大部分, 夜间出现最大风速的概率远高于白天; 低空急流发生高度大部分在飞机起飞或着陆的范围内, 使飞机复飞概率增加, 对夜间航班影响更大。