中国南方地区冬季风降水异常的分析

1997/1998和1998/1999年冬季是中国南方典型的多雨年和少雨年,它们分别发生在El Ni~no年和La Nina年。为了了解这两个冬季降水异常的原因,通过对比分析方法对这两个冬季的大气环流和水汽输送的差异进行了研究。结果表明:多雨年与ENSO事件的暖期相联系,西风带槽脊偏东偏弱,东亚冬季风减弱,副热带高压增强,对流层低层距平流场上呈现两个反气旋和一个气旋性环流,中心位于长江流域的气旋性环流的垂直结构和形成机理与菲律宾海反气旋不同。少雨年赤道海温的距平分布及高低层环流系统都与多雨年几乎相反。研究还揭示,冬季中国南方地区的水汽主要来自南支西风带低槽前部的西南气流和南海—中南半岛上空的转向气流,水汽输送通道随高度有明显的变化。1997/1998年冬季加强的南支西风气流和菲律宾海异常反气旋有利于水汽向中国大陆输送;1998/1999年南支西风气流弱,中国东南沿海低层为冷性高压控制,两支水汽输送带都大大减弱。这种水汽输送的明显年际变化是造成这2年冬季南方降水明显差异的一个关键因子。     

春夏季青藏高原积雪对中国夏末秋初 降水的影响及其可能机制

本文首先利用最大协方差分析方法,探讨青藏高原积雪与中国降水之间的联系,发现中国夏末秋初（8～10月,简称ASO）降水与前期及同期高原积雪有着显著联系,当春夏季青藏高原西部多雪时,其后ASO中国长江及其以南地区多雨,而东部沿海的狭长区域少雨。进一步引入最大响应估计等方法,研究中国区域降水对高原积雪异常的响应及其可能的物理机制,结果表明,冬春季高原多雪异常可持续到夏季,并通过改变地表热力状况,导致ASO南亚高压减弱,同时在高、低空激发出两支波列:高层200 hPa波列沿中高纬西风急流传播,自高原经蒙古到达日本呈现明显的“负—正—负”位势高度异常传播,日本上空为气旋性异常环流;低层850 hPa波列起于高原,经孟加拉湾至中国南海,沿着西南气流传播,导致台湾附近的反气旋性异常环流,其西侧的偏南气流,将南海丰富的水汽输送至中国南部湖南、广西;而高层中心位于日本的气旋性异常环流西侧的偏北气流利于北方天气尺度扰动向南移动,它们为长江中下游及其以南地区多雨提供了有利条件。进一步计算定常波波数也表明,高层西风急流与低层西南季风气流作为波导,有利于高原上空的扰动沿着高、低空2支通道向东传播。由于东部沿海浙江、福建为正位势高度异常区,低层反气旋性异常环流则抑制了该区域的降水。     

Effects of El Ni?o Modoki on winter precipitation in Korea

This study compares the impacts of El Ni?o Modoki and El Ni?o on precipitation over Korea during the boreal winters from 1954 to 2009. Precipitation in Korea tends to be equal to or greater than the normal level during an El Ni?o Modoki winter, whereas there is no significant change during an El Ni?o winter. Greater than normal precipitation during El Ni?o Modoki was also found over the lower reaches of the Yangtze River, China and much of southern Japan. The latitudes of these regions are 5–10° further north than in southern China, where precipitation increases during El Ni?o. The following two anomalous atmospheric circulations were found to be causes that led to different precipitation distributions over East Asia. First, an atmospheric wave train in the lower troposphere, which propagated from the central tropical Pacific (cyclonic) through the southern Philippine Sea (anticyclonic) to East Asia (cyclonic), reached the southern China and northern Philippine Sea during El Ni?o, whereas it reached Korea and southern Japan during El Ni?o Modoki. Second, an anomalous local meridional circulation, which consists of air sinking in the tropics, flowing poleward in the lower troposphere, and rising in the subtropics, developed between the southern Philippine Sea and northern Philippine Sea during El Ni?o. During El Ni?o Modoki, however, this circulation expanded further to the north and was formed between the southern Philippine Sea and regions of Korea and southern Japan.     

Recent changes in the summer precipitation pattern in East China and the background circulation

This study documents the decadal changes of the summer precipitation in East China, with increased rainfall in the Huang-Huai River region (HR) and decreased in the Yangtze River region (YR) during 2000?C2008 in comparison to 1979?C1999. The main features of the atmospheric circulation related to the increased precipitation in the HR are the strengthened ascending motion and slightly increased air humidity, which is partly due to the weakened moisture transport out of the HR to the western tropical Pacific (associated with the weakened westerly over East Asia and the warming center over the Lake Baikal). The rainfall decrease in the YR is related to the weakened ascending motion and reduced water vapor content, which is mainly related to the weakened southwesterly moisture flux into the YR (associated with the eastward recession of the Western Pacific Subtropical High). The global sea surface temperature (SST) also shows significant changes during 2000?C2008 relative to 1979?C1999. The shift of the Pacific decadal oscillation (PDO) to a negative phase probably induces the warming over the Lake Baikal and the weakened westerly jet through the air-sea interaction in the Pacific, and thus changes the summer precipitation pattern in East China. Numerical experiments using an atmospheric general circulation model, with prescribed all-Pacific SST anomalies of 2000?C2008 relative to 1979?C1999, also lend support to the PDO??s contribution to the warming over the Lake Baikal and the weakened westerlies over East China.     

A numerical study on the winter monsoon and cold surge over East Asia

By using the improved regional climate model （RegCM_NCC）, a numerical study has been undertaken for the East Asia region over a period of 5 years （1998-2002） in an effort to evaluate the model＇s ability to reproduce the winter monsoon conditions that were observed. The results showed that the model can successfully simulate the basic characteristics of the winter monsoon circulations, including the location and intensity of the cold-surface, high-pressure system, as well as the wind patterns and the intensity of the winter monsoon. The simulated occurrence frequency and regions of the cold surge were consistent with the observations. The simulated rainfall distribution over China was consistent with the observations collected in South China. The features of the simulated moisture transport were also in good agreement with the observations that were derived from the NCEP reanalysis data, indicating that moisture transport coming from the Bay of Bengal trough plays a crucial role in supplying moisture needed for precipitation in South China. In addition, the moisture transport coming from the near-equatorial west-Pacific was also important. These two branches of moisture transport converged in South China, as a prerequisite for occurrence of the precipitation that was observed there. Heat budgets have shown that the development of a heat sink over the East Asian continent was remarkable and its thermal contrast relative to the neighboring seas was the important forcing factor for the winter monsoon activity. The simulation also indicated that the significant differences in circulation patterns and rainfalls during the winters of 1997/98 and 1998/99 were affected by cold and warm ENSO events, respectively. The above analysis demonstrated the model＇s ability to simulate the East Asian winter monsoon.     

Simulation of a Freezing Rain and Snow Storm Event over Southern China in January 2008 using RIEMS 2.0

The Regional Integrated Environmental Model System(RIEMS 2.0) with NCEP Reanalysis II is utilized to simulate the severe freezing rain and snow storm event over southern China in January 2008,which caused severe damage in the region.The relationships between the freezing rain process and the large-scale circulation,in terms of the westerly and low-level jets,water vapor transportation,and northerly wind area/intensity indices,were analyzed to understand the mechanisms of the freezing rain occurrence.The results indicate the following:(1) RIEMS 2.0 reproduced the pattern of precipitation in January 2008 well,especially for the temporal evolution of daily precipitation averaged over the Yangtze River valley and southern China;(2) RIEMS 2.0 reproduced the persistent trough in the South Branch of the westerlies,of which the southwesterly currents transported abundant moisture into southern China;(3) RIEMS 2.0 reasonably reproduced the pattern of frequencies of light and moderate rain,although it overestimated the frequency of rain in southern China.This study shows that RIEMS 2.0 can be feasibly applied to study extreme weather and climate events in East Asia.     

Impacts of the North India Ocean SST on the extremely cold winters of 2011 and 2012 in the region of Da Hinggan Mountains and its western areas in China

The study of the winter temperatures, averaged from the records of 11 observatories in the Da Hinggan Mountains and its western areas in China (DHM-WA), identified 11 extremely cold (≤???1.5 °C) and 13 extremely warm winters (≥?+?1.5 °C) during the past 60 years (1951–2010). The winters of 2011 and 2012 are another two extremely cold events. Aimed at exploring the climate causes, a comprehensive investigation is carried out on variations of some major atmospheric circulation components. Additionally, opposite circulation regimes are verified by examining the mean 500-hPa circulation patterns and sea level pressure (SLP) corresponding to 14 warm and 18 cold sea surface temperature (SST) phases over the North India Ocean (NIO) during the period of 1951–2010. Composite of an extremely cold winter usually includes a large and strong Siberian High, a deep East Asian trough to the west, an small and weak western Pacific Subtropical High to the east, a large North Polar vortex and a weakened westerly stream over Eurasia continent accompanied by a strong meridional winds from the polar region to lower latitude. Moreover, it has been found that a favorable circulation condition associated with the extremely cold winters to DHM-WA is mainly controlled by the SST over NIO in the previous warm season (June–September); This is primarily related to changes in the intensity of the Walker and Anti-Walker circulations, which subsequently influence the major circulation components and result in an extremely cold winter in DHM-WA.     

中国东南部冬季降水变化及其环流特征

利用1951-2011年中国160站降水资料及NCEP/NCAR再分析资料,分析了中国东南部冬季降水的年际变化及与之相关的环流和水汽输送特征。结果表明:中国东南部冬季降水年际差异较明显,当降水异常偏多(少)时,蒙古高压及中国广大南方地区海平面气压异常偏低(高),而亚洲附近的洋面上则异常偏高(低);500 hPa上,巴尔喀什湖附近的高压脊和东亚大槽均偏弱(强);高层东亚西风急流异常偏弱(强),中东地区急流异常偏强(弱);中国东部20~30°N出现显著异常上升(下沉)运动,低纬度地区出现异常下沉(上升)运动。影响中国东南部冬季降水的水汽输送主要有两支:来自西风带绕高原的南支气流,经过阿拉伯海和孟加拉湾向华南的输送水汽;来自低纬西太平洋,经南海向中国西南的水汽输送。此外,东亚冬季风与中国东南部冬季降水关系密切。     

Effects of atmosphere-ocean interaction on the interannual variability of winter temperature in Taiwan and East Asia

 This study investigated the ocean-atmosphere interaction effect on the winter surface air temperature in Taiwan. Temperature fluctuations in Taiwan and marine East Asia correlated better with a SST dipole in the western North Pacific than the SST in the central/eastern equatorial Pacific. During the warm (cold) winters, a positive (negative) SST anomaly appears in marine East Asia and a negative (positive) SST anomaly appears in the Philippine Sea. The corresponding low-level atmospheric circulation is a cyclonic (anticyclonic) anomaly over the East Asian continent and an anticyclonic (cyclonic) circulation in the Philippine Sea during the warm (cold) winters. Based on the results of both numerical and empirical studies, it is proposed that a vigorous ocean-atmosphere interaction occurring in the western North Pacific modulates the strength of the East Asian winter monsoon and the winter temperature in marine East Asia. The mechanism is described as follows. The near-surface circulation anomalies, which are forced by the local SST anomaly, strengthen (weaken) the northeasterly trade winds in the Philippine Sea and weaken (strengthen) the northeasterly winter monsoon in East Asia during warm (cold) winters. The anomalous circulation causes the SST to fluctuate by modulating the heat flux at the ocean surface. The SST anomaly in turn enhances the anomalous circulation. Such an ocean-atmosphere interaction results in the rapid development of the anomalous circulation in the western North Pacific and the anomalous winter temperature in marine East Asia. This interaction is phase-locked with the seasonal cycle and occurs most efficiently in the boreal winters. Received: 22 October 1999 / Accepted: 5 June 2000     

Decadal Anomalies of Winter Precipitation over Southern China in Association with El Nio and La Nia

Using multiple datasets, this paper analyzes the characteristics of winter precipitation over southern China and its association with warm and cold phases of E1 Nifio-Southern Oscillation during 1948 2011. The study proves that E1 Nifio is an important external forcing factor resulting in above-normal winter precipitation in southern China. The study also reveals that the impact ofLa Nifia on the winter precipitation in southern China has a decadal variability. During the winter of La Nifia before 1980, the East Asian winter monsoon is stronger than normal with a deeper trough over East Asia, and the western Pacific subtropical high weakens with its high ridge retreating more eastward. Therefore, anomalous northerly winds dominate over southern China, leading to a cold and dry winter. During La Nifia winter after 1980, however, the East Asian trough is weaker than normal, unfavorable for the southward invasion of the winter monsoon. The India-Burma trough is intensified, and the anomalous low-level cyclone excited by La Nifia is located to the west of the Philippines. Therefore, anomalous easterly winds prevail over southern China, which increases moisture flux from the tropical oceans to southern China. Meanwhile, La Nifia after 1980 may lead to an enhanced and more northward subtropical westerly jet over East Asia in winter. Since southern China is rightly located on the right side of the jet entrance region, anomalous ascending motion dominates there through the secondary vertical circulation, favoring more winter precipitation in southern China. Therefore, a cold and wet winter, sometimes with snowy and icy weathers, would occur in southern China during La Nifia winter after 1980. Further analyses indicate that the change in the spatial distribution of sea surface temperature anomaly during the La Nifia mature phase, as well as the decadal variation of the Northern Hemisphere atmospheric circulation, would be the important reasons for the decadal variability of the La Nifia impact on the atmospheric circulation in East Asia and winter precipitation over southern China after 1980.     

与厄尔尼诺和拉尼娜相联系的中国南方冬季降水的年代际异常特征

利用NCEP/NCAR再分析大气环流资料、哈得来中心海温资料、中国700多站降水资料以及全球格点降水资料,详细分析了中国南方冬季降水异常的特征,并揭示了其所对应的欧亚大气环流和东亚冬季风异常与ENSO事件的联系,以及ENSO暖/冷位相对其影响的非对称性。研究进一步证明了厄尔尼诺是导致中国南方冬季降水偏多的重要外强迫因子,并指出拉尼娜对中国南方冬季降水的影响表现出明显的年代际变化特征。1980年之前的拉尼娜年冬季,东亚冬季风显著偏强,东亚大槽偏深,西北太平洋副热带高压偏弱偏东,中国南方受一致偏北风影响,气温偏低,降水偏少,多表现为冷干的气候特征。但1980年之后的拉尼娜年冬季,东亚大槽偏弱,印缅槽偏强,同时在菲律宾以西激发出异常气旋性环流,使得异常偏东风控制中国南方,有利于热带水汽输送增强,因此降水偏多。同时,1980年之后的拉尼娜事件还使得东亚副热带西风急流偏强偏北,中国南方处于急流入口区的右侧,通过二级环流使得中国南方上空的上升运动偏强,有利于降水偏多。因此,1980年之后的拉尼娜年冬季,中国南方易表现出冷湿的气候特征,有时也容易发生低温雨雪冰冻灾害。进一步分析表明,1980年以后拉尼娜成熟期海温异常空间分布型的变化,以及北半球大气环流的年代际变化可能是导致拉尼娜对东亚大气环流的影响在1980年之后发生变化的重要原因。     

1997—1998年青藏高原大气低频振荡及对降水影响

利用1979—1998年NCEP/DOE逐日再分析资料和国家气象信息中心的常规观测站资料,研究了1997/1998年冬季、1998年夏季青藏高原 (简称高原) 季风的低频振荡特征,研究夏季高原和周边区域高低层大气低频环流系统的配置及其与我国降水的联系。结果表明:1997/1998年冬季和1998年夏季,高原季风不仅表现出很强的30~60 d的周期振荡特征,还伴随有较强的准双周低频振荡;相应区域对流层上层200 hPa上的环流系统则是30~60 d为主的周期变化。1998年夏季,高原地面气压也存在两个频带的低频振荡变化,且其强度存在明显的经向变化,即自南向北30~60 d低频振荡信号有逐渐减弱趋势,准双周信号则呈增强趋势。对30~60 d的低频信号而言,高原夏季风低频信号较强 (弱) 时,高原地面表现为低频低 (高) 压环流系统,在同纬度带的我国东部地区和西太平洋沿岸,是较强的低频北 (南) 风和低 (高) 压环流系统;相应地,在80°~90°E之间,自孟加拉湾到我国西北中部地区,是低频反气旋-气旋-反气旋的经向低频波列;受低频环流系统影响,高原东部、长江中下游地区降水偏多 (少)、川西高原、云南西南部降水偏少 (多)。     

年代际气候预测系统IAP DecPreS的海洋同化试验在西北太平洋的海温偏差及其对亚洲夏季风的影响

本文分析了中国科学院大气物理研究所年代际气候预测系统IAP DecPreS的海洋同化试验（简称EnOI-IAU试验）在西北太平洋地区的海表面温度（SST）年循环的模拟技巧,并通过对比IAP DecPreS系统自由耦合历史气候模拟试验结果,在包含海气耦合过程的框架下讨论了耦合模式中西北太平洋夏季SST模拟差异,及其对亚洲季风区夏季季风降水模拟的影响。结果表明,EnOI-IAU试验较好地模拟出了西北太平洋各个季节的SST空间分布,并显著减小了原存在于历史气候模拟试验中持续全年的SST冷偏差。混合层热收支诊断分析表明,包含同化过程在内的海洋过程的模拟差异对西北太平洋海温的模拟提升有重要贡献。夏季,EnOI-IAU试验模拟的印度季风伴随的低层西风较观测偏东、偏强,且高估了赤道西太平洋区域的降水量值、低估了印度洋区域的降水量值。水汽收支分析显示,气旋式环流异常造成的水汽辐合异常是造成亚洲季风区降水模拟差异的主要原因。研究表明,较之历史模拟试验,EnOI-IAU试验中夏季西北太平洋地区SST增暖造成局地对流增强,进而使得局地产生异常上升运动,水汽辐合增强,造成西北太平洋地区降水模拟偏多,激发出低层西风异常及赤道外气旋式环流异常。该低层西风异常导致了北印度洋地区低层辐散异常,减小了原存在于历史试验中印度洋地区的正降水偏差。西北太平洋气旋式环流异常一方面增强了印度夏季风伴随的低层西风,使得更多的水汽从阿拉伯海输送到西太平洋暖池区域,增强了该区域的降水量;另一方面,该气旋式环流异常减小了历史模拟试验中中国南部区域偏强的低层风速,进而提升了模式对东亚低层西南风的模拟能力。     

青藏高原冬季1月绕流的变化特征及其对中国气候的影响

利用1979～2019年NCEP/NCAR再分析资料和中国地面基本气象要素日值数据集（V3.0）的气温和降水资料,首先定义了客观表征冬季青藏高原南北两支绕流变化的指数,然后分析了其不同的变化特征,并采用相关分析、合成分析等方法初步研究了青藏高原南北两支绕流异常变化对中国气温和降水的影响机制。主要结果有:（1）青藏高原冬季北支绕流和南支绕流之间呈显著的负相关;北支（南支）绕流强、南支（北支）绕流弱时,对流层中低纬度地区从高原西部到我国东部沿岸为一个大范围的异常反气旋式（气旋式）环流系统,500 hPa高原的中部为一个异常反气旋（气旋）环流中心。（2）青藏高原冬季南北两支绕流的变化对中国冬季天气气候有显著影响。当青藏高原北支绕流强（弱）时,中国除东北是气温偏低（高）、降水偏多（少）外,河套、青藏高原及长江以南则是气温偏高（低）、降水偏少（多）;当南支绕流强（弱）时,中国气温普遍偏低（高）,东北及新疆北部是降水偏少（多）,南方大部分地区是降水偏多（少）。（3）分析高原绕流异常变化对中国天气气候的影响机制表明:当青藏高原北支绕流强、南支绕流弱时,中国东部35°N以北的对流层中都是异常西北风,35°N以南都是异常东北风,受高原异常纬向绕流影响,对流层大气为明显的“正压结构”;相应的对流层底层从南到北为一致的异常西南风,850 hPa以上35°N的之间为反气旋式切变和下沉运动异常,300 hPa以下异常偏暖,这些条件加强了下沉增温,导致中国东部气温偏高、降水偏少。当青藏高原南支绕流强、北支绕流弱时,对流层中的纬向风异常则为明显的“斜压特征”,异常西风呈现为从对流层低层到高层、低纬度到高纬度的倾斜的带状特征,其下方自华南近地面到华北200 hPa的“三角形”状异常东风,配合相应的经向风异常和华南到华北的异常上升运动,低层为“三角形”状的异常冷气团向南切入到中国南海,中上层为异常偏暖的西南气流在冷气团上自南向北爬升到中高纬度地区,导致中国大范围的气温异常偏低、降水偏多。     

东西风廓线特征与大气运动平衡态定常波的相关关系及共振条件的研究

本文采用简化数学模型探讨了东、西风廓线特征与外源强迫下大气环流平衡态定常波结构的相关关系。文中采用实际观测资料研究了西风廓线特征与大气环流型季节特征之间的联系。研究表明,西风廓线冬、夏季节差异与中、高纬度西风槽“冬三夏四”波数差气候特征有关,且低纬强东风切变可作为赤道东风波周期振荡成因之一。冬夏西风廓线季节特征可导致大地形强迫效应、海陆加热因子影响作用的显著季节差异。研究还揭示了大气环流型优势波转换的基流特征影响效应,并导出了流场与纬向加热强迫源共振状态的西风廓线特征函数与临界曲线。     

Factors favorable to frequent extreme precipitation in the upper Yangtze River Valley

Extreme precipitation events in the upper Yangtze River Valley (YRV) have recently become an increasingly important focus in China because they often cause droughts and floods. Unfortunately, little is known about the climate processes responsible for these events. This paper investigates factors favorable to frequent extreme precipitation events in the upper YRV. Our results reveal that a weakened South China Sea summer monsoon trough, intensified Eurasian-Pacific blocking highs, an intensified South Asian High, a southward subtropical westerly jet and an intensified Western North Pacific Subtropical High (WNPSH) increase atmospheric instability and enhance the convergence of moisture over the upper YRV, which result in more extreme precipitation events. The snow depth over the eastern Tibetan Plateau (TP) in winter and sea surface temperature anomalies (SSTAs) over three key regions in summer are important external forcing factors in the atmospheric circulation anomalies. Deep snow on the Tibetan Plateau in winter can weaken the subsequent East Asian summer monsoon circulation above by increasing the soil moisture content in summer and weakening the land–sea thermal contrast over East Asia. The positive SSTA in the western North Pacific may affect southwestward extension of the WNPSH and the blocking high over northeastern Asia by arousing the East Asian-Pacific pattern. The positive SSTA in the North Atlantic can affect extreme precipitation event frequency in the upper YRV via a wave train pattern along the westerly jet between the North Atlantic and East Asia. A tripolar pattern from west to east over the Indian Ocean can strengthen moisture transport by enhancing Somali cross-equatorial flow.     

青藏高原南、北积雪异常与中国东部夏季降水关系的数值试验研究

青藏高原冬、春积雪有着显著的南、北空间差异,本文利用通用地球系统模式（CESM）设计了增加高原南、北冬、春积雪的敏感性试验,结果表明:当高原南部冬、春积雪异常偏多,长江及其以北地区夏季降水偏多,华南大部分地区夏季降水偏少;而当高原北部冬、春积雪异常偏多,华北及东北地区夏季降水偏多,长江下游南部地区夏季降水偏少,雨带更偏北。青藏高原南、北部冬、春积雪异常影响中国东部夏季降水的物理机制的分析结果表明,高原不同区域（南部和北部）冬、春积雪异常引起的非绝热加热异常效应都可持续到夏季,且北部积雪异常持续时间更长。高原南部和北部积雪异常偏多均会减弱高原北侧上空大气的水平温度梯度,进而减弱高原北侧西风急流的位置及强度,进而影响下游出口区处急流的强度和位置,且高原北部积雪异常偏多的影响更大。当高原南部积雪异常偏多,急流出口区的西风急流加强且偏南;而高原北部积雪异常偏多,出口区的西风急流减弱且偏北。相应地,对流层中层500 hPa西太平洋副热带高压减弱,低层850 hPa异常反气旋环流,影响中国东部地区水汽输送,从而影响了中国东部地区夏季雨带的变化。当高原南部积雪异常偏多,异常反气旋性环流位于东海附近,有利于更多水汽输送至长江流域,华南水汽输送减少;当高原北部积雪异常偏多,异常反气旋性环流相对偏北,更有利于华北及东北水汽输送,雨带偏北。     

冬半年南支西风中Rossby波传播及其与南支槽形成的关系

利用1948—2005年的10月—次年5月NCEP/NCAR再分析资料对西风急流中Rossby波的传播及其与冬半年副热带南支西风槽形成的关系进行研究, 结果表明:冬半年亚洲副热带西风急流下方存在3个南支波动, 分别位于阿拉伯海、孟加拉湾和我国华南地区, 其中孟加拉湾南支槽变率最小, 是半永久性低压槽; 从北非、阿拉伯海到孟加拉湾的“-+-”遥相关波列表明南支槽与北非槽呈正相关, 与阿拉伯海槽呈反相关。在西风波动从北非东传到孟加拉湾的过程中, 往往会在阿拉伯海有所停顿, 这种由西向东的传播过程约20 d一次, 具有明显的低频振荡特征; 源自北非的定常Rossby波能量沿着急流波导传播到孟加拉湾, 可能是南支槽明显增幅的一个主要机制; 另外, 从青藏高原东西两侧南下的冷空气活动也是南支槽加深发展的一个重要因素。     

Moisture transport between the South Atlantic Ocean and southern Africa: relationships with summer rainfall and associated dynamics

Moisture exchange between the South Atlantic and southern Africa is examined in this study through zonal moisture transport. Along the west coast of southern Africa, a multivariate analysis of the zonal flow of moisture computed from NCEP-DOE AMIP II Re-analyses reveals a primary mode of variability typical of variations in intensity and of the latitudinal migration of the circulation associated with the midlatitude westerlies and the South Atlantic anticyclone. In austral summer (January–February), this mode, referred to as the South Atlantic midlatitude mode, is found to be well correlated with rainfall over southern Africa (i.e. to the south of the upper lands surrounding the Congo basin). Its positive/negative phases are found to correspond with surface pressures changes over the South Atlantic region in austral summer when the South Atlantic anticyclone is shifted northward/southward respectively. Such changes are accompanied by dipole-like SST anomalies in the midlatitude South Atlantic Ocean, while simultaneous SST anomalies with a similar structure are also found over South Indian Ocean regions. In January–February, positive/negative events linked to the South Atlantic midlatitude mode are marked by meridional shifts (northward/southward) and weakening/strengthening of the ITCZ over the southern tropics, together with modulations in intensity (weakened/sustained) of the Angola low, which could act as a tropical source of moisture for Tropical Temperate Troughs (TTTs). In association with a strengthened/weakened zonal component of the southern extension of the African Easterly Jet (AEJ), this could modulate the meridional transfer of moisture south of 15°S to the advantage/detriment of Angolan coastal regions, where above/below rainfall are expected. Variations in the latitudinal position (northward/southward) of the South Atlantic anticyclone, and thus of the midlatitude westerlies, are also found to reduce/favour moisture advection towards southern Africa subtropics allowing the southern Indian trades to penetrate less/more over the subcontinent south of 25°S. This would create a situation where convection processes are inhibited/supported within the SICZ/TTTs region resulting in drier/wetter conditions locally for positive/negative events respectively.     

Diagnostic Comparison of Wintertime East Asian Subtropical Jet and Polar-Front Jet: Large-Scale Characteristics and Transient Eddy Activities

Diagnostic comparison of the East Asian subtropical jet (EASJ) and polar-front jet (EAPJ) in winter season is carried out by using the ERA-40 dataset. The large-scale circulation characteristics and synopticscale transient eddy activities (STEAs) associated with the EASJ and EAPJ are examined. The results show that the EASJ and EAPJ in the upper-level monthly mean data have no clear geographical border, while the distribution of the numbers of jet cores from the daily data exhibits a distinct boundary at the latitudes of the northern Tibetan Plateau. The two areas with large numbers of jet cores correspond to the EASJ and EAPJ regions. The analysis of STEAs over the East Asian region shows a spatial match of STEAs with the EASJ and EAPJ in winter: the strong EASJ is located within the weak southern branch of the STEA while the relatively weak EAPJ appears within the active northern branch of the STEA, indicating that the EAPJ is the jet coexisting with the STEA. Further analysis shows two anomalous modes of the winter EAPJ: the anomalous anticyclonic/cyclonic circulation and the weakened/strengthened local westerly wind. The large-scale circulation anomalies in the Northern Hemisphere related to the first mode are concentrated in the Eurasian mid to high latitudes, and are also influenced by the anomalous circulation in the upstream area. When the local westerly wind over the EAPJ region is weakened/strengthened, the westerly jet in the eastern part of the EASJ and that in the western Pacific region show opposite variations. The corresponding anomalous atmospheric circulation demonstrates the Eurasian (EU) pattern. The EAPJ anomalies are also closely linked with the STEA anomalies over East Asia. The anomalies in the northern branch of the STEA propagate as a wave train along its axis into the East Asian coastal waters, and then migrate eastward to the oceanic region. However, the ones near the southern branch are trapped over the eastern part of East Asia and its coastal waters at 200 hPa.