THE RELATIONSHIP BETWEEN HORIZONTAL VORTICITY INDUCED BY VERTICAL SHEAR AND VERTICAL MOTION DURING A SQUALL LINE PROCESS

The horizontal vorticity equation used in this study was obtained using the equations of motion in the pressure coordinate system without considering friction, to reveal its relationship with vertical shear. By diagnostically analyzing each term in the horizontal vorticity equation during a squall line process that occurred on 19 June 2010, we found that the non-thermal wind term had a negative contribution to the local change of upward movement in the low-level atmosphere, and that its impact changed gradually from negative to positive with altitude, which could influence upward movement in the mid- and upper-level atmosphere greatly. The contribution of upward vertical transport to vertical movement was the largest in the low-level atmosphere, but had negative contribution to the upper-level atmosphere. These features were most evident in the development stage of the squall line. Based on analysis of convection cells along a squall line, we found that in the process of cell development diabatic heating caused the subsidence of constant potential temperature surface and non- geostrophic motion, which then triggered strong convergence of horizontal acceleration in the mid-level atmosphere and divergence of horizontal acceleration in the upper-level atmosphere. These changes of horizontal wind field could cause a counterclockwise increment of the horizontal vorticity around the warm cell, which then generated an increase of upward movement. This was the main reason why the non-thermal wind term had the largest contribution to the strengthening of upward movement in the mid- and upper-level atmosphere. The vertical transport of large value of horizontal vorticity was the key to trigger convection in this squall line process.     

乌鲁木齐国际机场一次强东南大风天气分析

对乌鲁木齐国际机场2003年11月12日出现的强东南大风天气过程,利用常规天气资料和机场跑道自动观测系统(AWOS)采集的实时观测资料,对机场东南大风天气形势、机场跑道附近气象要素和水平风切变演变特征、高空风垂直分布特征等方面进行了分析,给出了东南大风的成因。     

STRUCTURE FEATURES AND COMPOSITE ANALYSIS OF CONVECTIVE CELLS IN A WARM SECTOR HEAVY RAINFALL EVENT OVER SOUTHERN CHINA

This paper uses the ARW-WRF model to carry out a numerical simulation of a warm-sector heavy rainfall event over southern China on the 22–23 May, 2014. A composite analysis method was used to analyze the evolution process and structural features of the convective cells on a convection line during this rainfall event. This analysis identified three stages: (1) Stage of activation: the equivalent potential temperature surfaces as lower layers start to bulge and form warm cells and weak vertical convective cloud towers which are subject to the impact of low-level warm moist updrafts in the rainfall sector; (2) Stage of development: the warm cells continue to bulge and form warm air columns and the convective cloud towers develop upwards becoming stronger as they rise; (3) Stage of maturity: the warm air columns start to connect with the stable layer in the upper air; the convective cloud tower will bend and tilt westward with each increasing in height, and the convection cell is characterized by a “crescent-shaped echo” above the 700hPa plane. During this stage the internal temperature of the cell is higher than the ambient temperature and the dynamic structural field is manifested as intensive vertical upward movement. The large-value centers of the northerly and westerly winds in the middle layer correspond to the warm moist center in the cells and the relatively cold center south of the warm air column. Further analysis shows that the formation of the “crescent-shaped” convective cell is associated with horizontal vorticity. Horizontal vorticity in the center and west of the warm cell experiences stronger cyclonic and anticyclonic shear transformation over time; this not only causes the original suborbicular cell echo shape to develop into a crescent-like shape, but also makes a convection line consisting of cells that develop to the northwest.     

基坑水平位移监测新方法及效用研究

基于水平角度、水平距离观测值与基坑水平位移之间的内在相关关系,提出了一种"自由设站余弦定理法",该方法具有可以根据工程现场实际情况自由设站、无需加密平面控制点、无需测试人员后视定向、作业过程更加简单快捷、通用性更强等优点;模拟试验数据计算结果表明,该方法可以取得较高的监测精度,完全可以满足基坑水平位移监测工作的需要。     

引发2011年8月宁夏持续高温天气的青藏高压结构分析

利用常规气象观测资料、中尺度区域自动站逐时地面资料及NCEP/NCAR 1°×1°再分析资料等,对引发2011年8月6-10日宁夏中北部连续5天出现≥35℃的高温天气的青藏高压水平和垂直结构进行了天气学分析.结果表明:青藏高压是一个深厚的暖性负涡度系统,它与西风带长波脊的同位相叠加使得高原上空的长波脊和暖高压稳定加强,受其影响,青藏高压外围586 dagpm线东移越过高原后稳定维持在85°～105°E附近,高压脊线北界伸展到40°～42°N,西北地区大范围长时间处在584 dagpm以上的青藏高压和1000 hPa以下的地面热低压控制区域内;高压上空在中纬度极锋急流的作用下,高原东部存在“高空辐合、低空辐散”的环流配置导致高原东部维持较强的下沉运动,处在下沉区的宁夏上空晴朗少云,湿度小,风力相对较大,地面增温和蒸发强烈,地面感热远远大于潜热,有利于出现以“干热”为主的持续高温天气.在此基础上,文章提出了宁夏夏季高温的概念模型.     

带横隔板局部开孔沉箱在斜向波作用下的受力研究

基于线性势流假定,对斜向波作用下带横隔板局部开孔沉箱防波堤的水平波浪力进行了理论研究。给出了开孔沉箱法向水平力和横隔板受力的理论计算方法,在极限情况下波浪力的计算结果与文献中的已有结果一致。利用数值算例分析了开孔沉箱总水平力的主要影响因素。开孔沉箱法向总水平力的减小主要集中于结构上半部分波浪影响范围以内。增加单个开孔沉箱的长度有利于减小结构所受总水平波浪力。当波浪入射角或沉箱前开孔墙孔隙影响系数幅值较大时,开孔沉箱横隔板上总水平力的最大值要超过相应的沉箱法向总水平力,此时要注意横隔板的强度问题。     

GPS与数字水准仪相结合进行三维控制网的布设

通过三维控制网的实际布设,对GPS平面控制网的精度和数字水准仪布设的高程控制网的精度进行了分析探讨,并对二者如何更加有效的结合提出了几点有益的见解。     

边界层风廓线雷达测风精度分析

利用CLC-11-D型边界层风廓线雷达的5波束观测数据,对比分析了晴空、稳定性降水和对流性降水等不同类型气象条件下边界层风廓线雷达测风的准确性,并对2016年3月1日—2017年2月28日共计7300时次的晴空观测资料进行了测风质量评估,得出结论如下:在晴空条件下大气均匀稳定,水平风速和风向测量精度要优于稳定性降水和对流性降水天气,降水出现前后环境大气扰动较大是导致稳定性降水和对流性降水天气下测风精度较差的原因;150 m以下近地层高度的测风质量较差,与地杂波干扰较强有关;夏季有效探测高度最高可达6300 m左右,春秋季有效探测高度比较接近,分别为2000 m和2500 m左右,冬季有效探测高度最低,仅为1100 m左右;4个季节测风质量评估达标高度分别为900、4000、2200 m和1100 m,大气环境的湿度条件和水平风速、风向标准差的波动是影响测风质量评估的重要因素。     

关于频率电磁测深几个问题的探讨(五)——频率电磁测深中电磁场波型及意义

引出水平分层大地面上水平电偶极源及垂直磁偶极源的电磁场分量表达式,对式中核函数进行了变换,分析所含的波型及其与场区的关系,指出了TE型场、TM型场和TEM型场穿透地层的能力。根据波型与地层作用特点,优化电磁场分量,以提高频率电磁测深的探测效果。     

归一化总水平导数法在位场数据解释中的应用

本文提出归一化总水平导数法,通过对总水平导数进行空间归一化计算实现了异常体水平位置和深度的估计,此外还推导出基于归一化总水平导数的欧拉反褶积法来估算地下地质体的空间位置,两种方法反演结果的相互验证可有效地提高反演结果的可信度.理论模型试验证明空间归一化总水平导数法和归一化总水平导数欧拉反褶积法均能有效地完成异常体的水平位置和深度的估计,所获得的位置参数与理论值相一致.在利用归一化总水平导数法进行磁异常解释时,对数据进行化磁极计算可得到更加准确的结果.将其应用于实际航磁数据的解释,获得了岩脉的大致分布特征.