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1.
利用站点降水资料和再分析资料针对华南地区5—8月的持续性强降水过程,分析了低频异常非绝热加热的时空分布特征及其对低频大气环流的可能反馈作用。得到如下结论:5—6月和7—8月华南持续性强降水期间10—30 d低频非绝热加热的演变特征有所不同,5—6月持续性强降水发生前低频非绝热加热大值区从30°N(107°—115°E)以北向南传播发展至华南地区,而在7—8月降水前非绝热加热大值区从中国南海中部向西北方向传播,并在降水最强盛期到达华南。异常环流型控制着持续性强降水的强度和位置,从而决定异常凝结潜热的演变特征。异常凝结潜热则是通过影响涡度倾向变化而对大气环流有一个反馈作用。对于发生在华南5—6月和7—8月的这2组持续性强降水过程,当降水处于发展阶段,在低频非绝热加热作用项和低频涡度平流项的共同作用下,华南上空中层存在显著的10—30 d低频正涡度倾向变化,有利于低频气旋式环流的进一步发展。非绝热加热作用项主要由加热率的垂直梯度决定,涡度平流项则与气候背景风场有密切关系。5—6月持续性强降水期间涡度平流项位于非绝热加热项东侧,而7—8月持续性强降水期间涡度平流项位于非绝热加热项北侧。在持续性强降水的衰亡期,由于非绝热加热项和涡度平流项转为负值,华南被负涡度倾向变化控制,低频气旋式环流迅速消亡。 相似文献
2.
近30年我国南方区域持续性暴雨过程的分类研究 总被引:5,自引:0,他引:5
利用中国站点日降水资料对1981~2011年我国南方地区区域持续性暴雨(PHREs)进行了分类研究。按照区域内至少连续5 d或5 d以上有不小于10个格点[分辨率0.25o(纬度)×0.25o(经度)]出现大于等于50 mm降水且相邻两日雨带重合率不小于20%的标准,采用客观分析的方法分别挑选出我国江淮区域和华南区域PHREs。江淮区域非台风影响的PHREs 31例,集中发生在6月中旬到7月中旬,平均持续8.29 d,华南非台风影响的PHREs 34例,集中发生在6~7月,平均持续6.24 d,这两类事件的发生频次和强度均呈年代际增长。江淮区域受台风影响的PHREs 4例,集中发生在7月中下旬到8月初。华南受台风系统影响的PHREs 31例,集中发生在7~9月,此类事件的发生频次和系统强度在2000年以后均明显上升。采用场相关的客观分类方法对非台风影响的PHREs进行较为细致的分类,将江淮区域持续性暴雨事件分为A型(主雨带在长江以南)、B型(主雨带在长江以北)和C型(主雨带在长江沿江地区),将华南区域持续性暴雨事件分为E型(主雨带在云贵高原以东)和F型(主雨带位于云贵高原和广西),该分类将为下一步的机制研究提供帮助。 相似文献
3.
应用常规观测、海口多普勒回波及NCEP1×1°再分析等资料,对2008年10月12~15日海南特大暴雨成因进行诊断分析,并揭示了暴雨过程中的多普勒回波特征。结果表明:导致海南岛产生强降水的主要原因是热带低压移动缓慢和弱冷空气的低层入侵;当冷暖空气交绥,大气温湿结构发生突变,θse面陡立造成对流系统斜压发展,激发位势不稳定能量释放。正差动假相当位温平流意味着低层暖湿空气的平流大于高层,加强了层结对流不稳定发展;在斜压扰动作用下,对流层中层正差动涡度平流和低压东侧的暖平流破坏了海南岛的准地转平衡,动力强迫和热力强迫共同作用激发了次级环流,导致暴雨区上空的垂直运动的发展,促使暴雨增强。充沛的水汽输送及水汽的强烈辐合,为暴雨发生的有利水汽条件。多普勒径向速度揭示了暴雨区低层冷平流高层暖平流、风向风速的垂直切变大的垂直结构以及持续性的强烈辐合等等特征,回波停滞和"列车效应"使降水增幅,降水回波的性质差异,可造成强降水区域分布的不同。 相似文献
4.
The evolution of the tropospheric temperature fields over Indian and South China Sea monsoon areas and their thermal mechanisms are compared and analyzed during the period from March to June, 1996. The results show that the onsets of the Indian and South China Sea summer monsoons are closely associated with the seasonal warming in the troposphere over the zonal belt of 10°N~30°N in these areas, which leads to the inversion of meridional temperature gradient. During the pre-onset period, the warming over the South China Sea monsoon region is mainly due to the warm horizontal advection and diabatic (latent) heating processes. Meanwhile, the warming is suppressed by the vertical adiabatic process (cooling). In spring over the Indian monsoon region, the significant adiabatic heating due to the subsidence motion, which compensates the cooling due to the strong cold advection and diabatic cooling processes, results in a larger warming rate than over the South China Sea monsoon region. However, the meridional temperature gradient over the Indian monsoon region is so large during the late winter and early spring that it takes longer time to warm the troposphere to have the reversion of meridional temperature gradient than it does over the South China Sea monsoon region. It results in the phenomenon that the South China Sea summer monsoon generally breaks out earlier than the Indian summer monsoon. 相似文献
5.
Tingting MA Guoxiong WU Yimin LIU Zhihong JIANG Jiahui YU 《Journal of Meteorological Research》2019,(3):400-415
The external source/sink of potential vorticity (PV) is the original driving force for the atmospheric circulation. The relationship between surface PV generation and surface PV density forcing is discussed in detail in this paper. Moreover, a case study of the extreme winter freezing rain/snow storm over South China in January 2008 is performed, and the surface PV density forcing over the eastern flank of the Tibetan Plateau (TP) has been found to significantly affect the precipitation over South China in this case. The TP generated PV propagated eastward in the middle troposphere. The associated zonal advection of positive absolute vorticity resulted in the increasing of cyclo-nic relative vorticity in the downstream region of the TP. Ascending air and convergence in the lower troposphere developed, which gave rise to the development of the southerly wind. This favored the increasing of negative meridio-nal absolute vorticity advection in the lower troposphere, which provided a large-scale circulation background conducive to ascending motion such that the absolute vorticity advection increased with height. Consequently, the ascending air further strengthened the southerly wind and the vertical gradient of absolute vorticity advection between the lower and middle troposphere in turn. Under such a situation, the enhanced ascending, together with the moist air transported by the southerly wind, formed the extreme winter precipitation in January 2008 over South China. 相似文献
6.
为了解中期连续暴雨的成因, 进一步做好4—6月广东省致洪连续暴雨的中期预报, 用统计和合成分析方法, 对1961—2001年广东省前汛期连续暴雨过程的气候背景及中期环流特征进行了分析。分析结果表明:广东省6月出现连续暴雨的几率最大; 小波分析和最大熵谱分析表明, 广东省的连续暴雨存在准2~5年和10年左右的周期振荡, 未来几年发生连续暴雨的次数将增多; 用500 hPa候平均高度场资料, 对出现在广东省的前汛期连续暴雨过程的中期环流特征及高、低纬地区的环流演变特点进行了分析归纳, 总结出两类造成连续暴雨过程的中期环流特征的2条指标, 它们的共同特点为:中高纬度具有十分稳定的“西阻”和“东阻”, 中高纬的“东阻”和低纬120°E以东的正距平区相叠加, 使得低纬维持稳定的东高西低形势, 有利于出现连续暴雨过程。在此基础上利用欧洲中心500 hPa高度场未来1~5 d的格点逐日预报资料得到候平均图, 用动力-相似诊断方法作出2003—2005年广东省有无连续暴雨过程的中期趋势预报。 相似文献
7.
Persistent heavy rainfall events (PHREs) over South China during 1981–2014 were selected and classified by an objective method, based on the daily precipitation data at 752 stations in China. The circulation characteristics, as well as the dry-cold air and moisture sources of each type of PHREs were examined. The main results are as follows. A total of 32 non-typhoon influenced PHREs in South China were identified over the study period. By correlation analysis, the PHREs are divided into three types: SC-A type, with its main rainbelt located in the coastal areas and the northeast of Guangdong Province; SC-B type, with its main rainbelt between Guangdong Province and Guangxi Region; and SC-C type, with its main rainbelt located in the north of Guangxi Region. For the SC-A events, dry-cold air flew to South China under the steering effect of troughs in the middle troposphere which originated from the Ural Mountains and West Siberia Plain; whereas, the SC-C events were not influenced by the cold air from high latitudes. There were three water vapor pathways from low-latitude areas for both the SC-A and SC-C PHREs. The tropical Indian Ocean was the main water vapor source for these two PHRE types, while the South China Sea also contributed to the SC-C PHREs. In addition, the SC-A events were also influenced by moist and cold air originating from the Yellow Sea. Generally, the SC-C PHREs belonged to a warm-sector rainfall type, whose precipitation areas were dominated by southwesterly wind, and the convergence in wind speed was the main reason for precipitation. 相似文献
8.
利用NCEP1°×1°6 h再分析资料,对副热带高压与西风槽典型环流形势配合下发生的一次四川区域性暴雨过程的不同阶段进行对比分析。结果表明,前期暴雨天气过程,其动力条件占到了主导地位,具有明显的经向垂直环流圈和垂直上升运动支,而在副高断裂后较强冷空气作用下,在副高边缘发生的区域性暴雨过程受西风带槽前的能量锋区影响,动力强迫作用和热力强迫作用激发的次级环流,进一步加强了四川盆地垂直运动的发展;冷空气作用前期的暴雨过程和冷空气进入后副高边缘发生的区域性暴雨过程中暴雨区域内的假相当位温均强于高层,大气处于对流性不稳定层结状态,对四川盆地暴雨的增强也起了不可忽视的作用,但由副高控制到副高逐渐断裂,湿位涡的斜压扰动是逐渐增强的过程,导致倾斜垂直涡度发展,激发更为强烈的上升运动;副高与西风槽环流形势相配合的暖区暴雨过程水汽主要来自中低层孟加拉湾;而副高断裂后发生在副高边缘的区域性暴雨过程,水汽主要来自850hPa层南海和孟加拉湾,从对流层中到低层,四川盆地东部恰恰是冷暖气流的交汇处,偏南气流将海上充沛的水汽输送到盆地东部,为暴雨的发生提供充足的水汽条件,并与对流层低层秦岭附近的东北冷气流交汇。 相似文献
9.
在华南北部或长江流域有锋面雨带活动时,华南沿海常常会出现对流性强降水,突发性很强,给预报造成很大的困惑。文章采用多种观测资料、ERA-Interim 0.125°×0.125°逐6 h再分析资料,对2017年6月15~16日华南北部的锋面雨带及沿海强降雨过程开展分析,对比了二者降水特征与环境条件,重点探讨了该次过程华南沿海强降雨的对流触发与维持,揭示了一种由边界层风切变强迫造成涡度持续发展的动力效应。结果表明:(1)锋面雨带与华南沿海强降雨在降水特征上有显著差异,并各有特点。锋面雨带以大尺度层状云降水和弱对流性降水为主,降水强度东段弱西段强。沿海强降雨以对流性降水为主,局地性强、落区集中、强降雨持续时间长、夜发性明显。(2)水汽方程诊断发现沿海强降雨在边界层水平水汽平流项、垂直水汽输送项比锋面雨带东段具有更大量级,大气层结反映出更深厚的暖层、湿层与对流不稳定,是二者降水强度及性质差异的主要原因。(3)莲花山、峨眉嶂造成气流侧向摩擦与正面阻挡促使漯河河谷内垂直涡度发展,暖湿空气堆积上升并达到自由对流高度,触发了华南沿海最初的降水。夜间建立的西南风急流使边界层垂直风速切变增强,水平涡度倾斜部分转化为垂直涡度发展,与风速水平切变造成的垂直涡度叠加,是强降雨持续时间长的动力机制。海陆边界摩擦差异造成水平、垂直两个方向的风切变增强,共同强迫垂直涡度发展是此次强降雨过程对流维持的动力效应。(4)
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11.
一次广西暴雨过程的数值模拟及低涡系统分析 总被引:2,自引:1,他引:1
应用WRF中尺度数值模式对2008年6月12日广西地区的一次大暴雨过程进行了模拟,利用模式输出资料,对引发这次大暴雨的西南低涡的演变情况及其物理场特征进行了分析。结果表明,低涡暴雨的发生具有明显的不均匀性,暴雨主要出现在低涡东侧暖区切变线附近;暴雨过程中充沛的水汽主要来源于孟加拉湾和中国南海,水汽的辐合不仅是涡旋区降水的必要条件,还是低涡发展加强的一个有利因素;强降水与强上升运动及正涡度区有很好的对应关系,低涡低层有强不稳定能量积聚也是造成此次大暴雨的重要原因之一。 相似文献
12.
YU Zhenshou NI Donghong GAO Shouting MIN Jinzhong REN Hongxiang 《Acta Meteorologica Sinica》2008,22(2):224-238
Typhoons landing in the central and north of Fujian Province often seriously impact Zhejiang Province. Much attention has been given to exceptionally torrential rain in the South/North Yandang mountainous regions in the southeast of Zhejiang Province associated with typhoon-landing. Typhoon Haitang (2005) is a typical case of such a category, which landed in Huangqi Town of Lianjiang County in Fujian Province, and meanwhile greatly impacted Southeast Zhejiang. A numerical simulation has been performed with the PSU/NCAR non-hydrostatic model MM5V3 to study the torrential rain associated with Typhoon Haitang. The comparison of simulated and observed rainfalls shows that the MM5V3 was able to well simulate not only the intensity but also the locations of severe heavy rain of Typhoon Haitang, especially the locations of the south/north heavy rain center areas in the South/North Yandang mountainous regions. Meanwhile, the diagnostic analysis has been also carried out for better understanding of the severe heavy rain mechanism by using the model output data of high resolution. The diagnostic analysis indicates that the westward tilt of the axis of vorticity from lower layer to upper layer over the south heavy rain center area and the coupled structure of convergence in the lower layer and divergence in the upper level over the north heavy rain center area, were both propitious to stronger upward motion in the layers between the mid and upper atmosphere, and the secondary circulation induced by the vertical shear of the ambient winds further strengthened the upward motion in the heavy rain areas. After Haitang passed through Taiwan Island into the Taiwan Strait, the water vapor east of Taiwan Island was continuously transferred by typhoon circulation towards South Wenzhou, leading to the torrential rainfall in the South Yandang mountainous region south of Wenzhou. Subsequently~ Haitang moved northwards, the water vapor belt east of Taiwan Island slowly advanced northwards, the precipitation rate obviously enhanced i 相似文献
13.
Impact of tropical cyclone development on the instability of South Asian High and the summer monsoon onset over Bay of Bengal 总被引:2,自引:0,他引:2
Guoxiong Wu Suling Ren Jianmin Xu Dongxiao Wang Qing Bao Boqi Liu Yimin Liu 《Climate Dynamics》2013,41(9-10):2603-2616
This paper analyzes the evolution of the South Asian High (SAH) during and after the development of tropical cyclone Neoguri over the South China Sea (SCS) in mid-April 2008, the formation of tropical storm Nargis over the Bay of Bengal (BOB) in late April, and the Asian summer monsoon onset, as well as their interrelationships. Numerical sensitivity experiments are conducted to explore the underlying mechanism responsible for these seasonal transitions in 2008. It is demonstrated that strong latent heating related with tropical cyclone activities over the SCS can enhance the development of the SAH aloft and generate zonal asymmetric potential vorticity (PV) forcing, with positive vorticity advection to its east and negative advection to its west. Following the decay of the tropical cyclone, this asymmetric forcing leads to instability development of the SAH, presenting as a slowly westward-propagating Rossby wave accompanied by a westward shift of the high PV advection. A strong upper tropospheric divergence on the southwest of the SAH also shifts westward, while positive PV eddies are shed from the high PV advection and eventually arrives in the southern BOB. Such synoptic patterns provide favorable pumping conditions for local cyclonic vorticity to develop. The latent heating release from the cyclogenesis further intensifies the upper-layer divergence, and the lower and upper circulations become phase locked, leading to the explosive development of the tropical cyclone over the southern BOB. Consequently, a tropical storm is generated and the BOB summer monsoon commences. 相似文献
14.
本文使用常规观测资料、四川省自动站降水资料、0.1°×0.1°的FY-2E云顶亮温资料和1°×1°的NCEP再分析格点资料对2012年7月20~23日四川东部强降水过程的主要影响系统、水汽源地、动力、热力条件等进行诊断分析,结果表明:(1)本次暴雨过程中伴有500hPa高空槽东移至四川并向南加深发展,槽后冷空气与槽前暖湿气流在四川汇合,低层有低涡发展,配以高低空急流耦合的有利形势;(2)暴雨前期水汽主要来源于孟加拉湾,随着南海台风西进,其外围偏东气流向西输送增强,西南暖湿气流北上受到抑制,使得雨带南压;(3)降水以对流性降水为主,暴雨期间水汽凝结潜热在对流层中低层起主要作用,强上升运动将低层的潜热加热向上输送,形成高空的热源中心,强降水期间大气的加热是与大气的垂直上升运动密切相关的;在本次暴雨过程垂直输送项是视热源Q1和视水汽汇Q2的主要贡献者,尤其是在强降水阶段;(4)在低涡在发展阶段,低层正涡度局地变化项首先得到发展,在低涡减弱阶段,正涡度局地变化项的峰值中心由低层向中低层抬升;(5)中尺度对流系统与小时降水分布一致,MCS的发展是触发降水的重要因素之一。 相似文献
15.
台风“海棠”特大暴雨数值模拟研究 总被引:12,自引:1,他引:12
在福建中北部登陆的台风,往往会严重影响浙江,尤其值得注意的是台风引起特大暴雨经常会发生在浙江东南沿海的南雁荡山区和北雁荡山区,2005年在福建省连江黄歧登陆的台风"海棠"(0505)对浙江东南沿海造成严重影响,是这类台风比较典型个例。文中利用非静力模式MM5模拟"海棠"台风在浙东南沿海造成的特大暴雨,模拟结果与实况对比分析表明,模式较好地模拟了台风降水强度和分布,特别是成功模拟出南雁荡山区特大暴雨中心(南部暴雨区)和雁荡山区特大暴雨中心(北部暴雨区);运用高时空分辨率模拟资料对特大暴雨成因进行诊断分析表明,南部暴雨区涡度低层到高层向西倾斜结构和北部暴雨区高低空强辐散辐合的耦合结构有利于形成暴雨区强烈上升运动,环境风场垂直切变产生次级环流进一步加强暴雨区上升运动;暴雨区持续不稳定层结和特殊水汽输送通道为特大暴雨提供热力条件和水汽条件。最后对浙南闽北地形对台风特大暴雨影响进行数值敏感性试验表明,温州南、北雁荡山脉地形等高线与台风水汽输送路径正交是造成特大暴雨的重要原因,地形使暴雨增幅明显,地形越高对暴雨增幅越明显,降水分布更加不均匀。比较台风造成南、北特大暴雨条件,发现两者既有环境风场垂直切变产生次级环流进一步加强暴雨区上升运动、持续不稳定层结以及地形对暴雨增幅作用等相同之处,又有动力结构、维持持续不稳定层结条件以及水汽输送等不同之处。 相似文献
16.
将对流涡度矢量 (CVV) 应用于浅薄系统西南低涡引发的暴雨中,特别是将对流涡度矢量垂直分量 (Cz) 应用在2010年7月16—18日由西南涡引发的一次暴雨过程诊断中。研究了CVV垂直积分的各个分量与6 h累积降水量的关系,尤其是CVV垂直分量在西南涡暴雨过程中的指示意义。诊断结果表明:CVV垂直分量与西南涡引发的暴雨有一定对应关系,强降水发生时段与Cz垂直积分峰值出现的时间对应一致;在对流层低层850 hPa水平分布上,暴雨区位于CVV垂直分量的正值中心附近,偏向其梯度较大处;沿暴雨中心的CVV垂直分量,当对流层低层至高层呈现一致的正值时,暴雨强度会明显加强。 相似文献
17.
选取2008-2011年湖北省7个暖干类暴雨个例,利用GFS 0.5°×0.5°再分析资料进行合成分析。结果表明:湖北省暖干类暴雨过程中,正涡度平流不是大范围出现,而是以正涡度平流核的形式出现并随着风场流转,使暴雨区各层涡度平流的配置快速发生变化,容易引起上升运动的突然加强;暖平流从中高层扩展至整层,强暖平流中心出现在临近暴雨发生时的边界层,热力强迫导致低层强辐合,950 hPa上下强暖平流中心与暴雨点位置较一致,对暖干类暴雨的预报有较好的指示意义;中层干空气和低层暖湿空气的侵入是暴雨区对流不稳定增长的主要影响因子,均与副热带高压的西伸发展有关。 相似文献
18.
利用我国740个测站逐日降水资料和NCEP/NCAR逐日再分析资料,使用合成分析等方法,对华北夏季降水的年代际变化特征进行分析。结果表明:华北夏季降水的年代际变化与华北夏季雨带的年代际变化密不可分。在华北夏季降水偏多阶段,华北地区雨带降水量较大,华北雨带能够向西延伸,雨带位置大多数时间能够越过115°E,并且能够接近华北西部边界110°E,位置偏西;而在华北夏季降水偏少阶段,华北雨带降水量偏小,雨带虽然也能够越过115°E,但维持时间不长,且向西延伸并不明显,雨带位置很难接近华北西部边界110°E,位置偏东。华北雨带发生的年代际变化和东亚地区大气环流以及东亚夏季风的年代际变化有关。 相似文献
19.
在总结前人关于中国夏季雨型划分的研究成果及其存在的主要问题的基础上 ,对中国夏季雨型的划分进行了新的尝试。根据东部季风区夏季 ( 6~ 8月 )降水的客观气候规律及业务预报应用需要 ,利用经验正交分解、主成分分析、奇异值分解、聚类分析等数理统计方法 ,结合经验分析 ,对中国东部季风区 1 880年以来 1 2 0多年夏季降水进行了客观分型 ,将中国东部季风区夏季降水划分为两类四型 ,并进一步分析了各类雨型的大气环流成因。 相似文献
20.
2004年9月2—6日四川盆地中东部发生了一次持续性强暴雨过程。利用时间平均合成分析方法对强暴雨维持期间 (9月3日20:00—5日08:00, 北京时) 的探测资料进行合成平均, 再对合成平均资料做诊断分析, 以揭示持续性强暴雨过程持续期的平均特征。诊断分析显示, 台风西进导致稳定的环流以及中低层大量的水汽输送为暴雨持续提供了背景条件。在时间平均流场上, 与暴雨相联系的中尺度系统十分显著, 它在对流层中低层表现为准东西向的中尺度辐合带, 在对流层高层表现为中尺度辐散带, 两者垂直耦合为深厚系统。此外, 在暴雨持续期间, 对流层低层大气运动表现出强烈的非平衡特征, 这种非平衡的动力强迫作用支撑着低层强辐合的维持。 相似文献