A Study on Water Vapor Transport and Budget of Heavy Rain in Northeast China

The characteristics of moisture transport and budget of widespread heavy rain and local heavy rain events in Northeast China are studied using the NCEP--NCAR reanalysis 6-hourly and daily data and daily precipitation data of 200 stations in Northeast China from 1961--2005. The results demonstrate that during periods with widespread heavy rain in Northeast China, the Asian monsoon is very active and the monsoonal northward moisture transport is strengthened significantly. The widespread heavy rainfall obtains enhanced water vapor supply from large regions where the water vapor mainly originates from the Asian monsoon areas, which include the East Asian subtropical monsoon area, the South China Sea, and the southeast and southwest tropical monsoon regions. There are several branches of monsoonal moisture current converging on East China and its coastal areas, where they are strengthened and then continue northward into Northeast China. Thus, the enhanced northward monsoonal moisture transport is the key to the widespread heavy rain in Northeast China. In contrast, local heavy rainfall in Northeast China derives water vapor from limited areas, transported by the westerlies. Local evaporation also plays an important role in the water vapor supply and local recycling process of moisture. In short, the widespread heavy rains of Northeast China are mainly caused by water vapor advection brought by the Asian monsoon, whereas local heavy rainfall is mainly caused by the convergence of the westerly wind field.     

Moisture Transport in the Asian Summer Monsoon Region and Its Relationship with Summer Precipitation in China

The characteristics of moisture transport over the Asian summer monsoon region and its relationship with summer precipitation in China are examined by a variety of statistical methods using the NCEP/NC AR reanalysis data for 1948-2005.The results show that:1) The zonal-mean moisture transport in the Asian monsoon region is unique because of monsoon activities.The Asian summer monsoon region is a dominant moisture sink during summer.Both the Indian and East Asian monsoon areas have their convergence cente...     

南海夏季风北推时间及相关环流变化特征

利用1958—2004年NCEP/NCAR逐日再分析资料和我国730站降水资料分析了南海夏季风爆发后影响到华南地区的时间差异及其环流变化特征。结果表明:南海夏季风向北推进影响到华南地区的时间存在明显差异，最早的可以1 d就推进影响到华南地区，最晚的却要42 d，并且这种变化具有明显的年代际变化特征，即20世纪70年末以前，南海夏季风影响到华南地区的时间总体上要偏早，而70年代末以后，南海夏季风影响到华南地区的时间总体上要偏晚；当南海夏季风建立后，若东亚大槽较深，冷空气活动较活跃，索马里越赤道气流形成的西南风、110°~120°E地区越赤道气流形成的偏南风以及副热带高压西侧边缘的偏南风均偏弱，南亚高压和东亚地区急流位置偏南，就会使得南海夏季风影响到华南地区的时间偏晚，反之，则偏早；南海夏季风推进影响到华南地区的时间偏晚（早）年期间，索马里、105°E和130°E越赤道气流输送的水汽通量和西太平洋副热带高压南部的东南气流水汽输送均较弱（强），华南地区前汛期的锋面降水较强（弱）。     

近50年来中国夏季降水及水汽输送特征研究

利用1951-2006年中国448站夏季降水资料、NCEP/NCAR VersionⅠ的再分析资料,研究了近50年来中国夏季降水年代际变化特征及其分区,并从季风性水汽输送的变化角度出发,讨论了影响中国一些主要地区降水变化的可能机制.研究发现:(1)从总体上来说,自1951年至今,中国夏季降水存在3个突变时段,即1956-1960年,1980年前后以及1993年以后.且90°E以东突变后的主要变化特征都是多雨区由北向南传播,而90°E以西则是多雨区由南向北传播;2)近56年来就110°E以东的中国东部夏季降水而言,1980年以后多雨区由华北南移到长江中下游,又于1993年以后由长江中下游继续南移至华南;3)中国东部各地区降水和850 hpa风场、整层水汽输送场的相关分布一致表明,中国110°E以东各降水区以南为来自偏东偏南的季风性异常水汽输送,而以北为来自偏北风和相应的异常水汽输送,两者在降水区汇合造成风和水汽输送异常辐合.因而,西太平洋副热带高压南侧的东南季风及其异常水汽输送、北方冷槽的偏北风及其异常水汽输送是中国东部夏季降水异常的主要成员,这和一般认为的这些地区降水异常来自孟加拉湾的季风性异常水汽输送的观点不同,需要作进一步研究.总之,对于中国东部旱涝的形成,应该重点注意来自西北太平洋副热带高压西侧的直接或间接经南海到达的异常四南季风性水汽输送.     

Definition and Features of the North Edge of the East Asian Summer Monsoon

By using daily total precipitable water(TPW) amount from the ECMWF reanalysis(ERA-44a) data in 1958-2001,the north edge of the Asian sub-tropical summer monsoon is defined by a normalized precipitable water index(NPWI),and its climatology and interannual/interdecadal variability are examined.The results show that two monsoon systems(the Indian and East Asian monsoon systems) can be identified in terms of monsoon edge defined by the NPWI over Asia.The mean north edge goes in the west-east direction along ...     

1997年东亚夏季风异常活动在汛期降水中的作用

利用1997年逐日降水资料和国家气象中心提供的T63再分析资料，详细讨论了中国汛期降水及东亚夏季风活动的异常特征及其间的联系。结果表明，该年中国夏季降水及东亚夏季风活动均表现了突出的异常，东部雨带长期滞留在江南、华南一带，夏季风向北的推进很弱，主要活跃于较低纬度，最北仅至35°N，未能在黄河以北的地区建立，比起气候意义下夏季风北进的最高纬度偏南10°左右。在这一过程中，夏季风异常是主要雨带异常发展的重要影响因子，候大雨带的建立和北推均与季风的建立与活跃密切相关。进一步对大尺度水汽场的分析表明，夏季风的活动明显改变了大尺度水汽输送及辐合，进而影响和制约了主要雨带的分布。夏季风爆发后，南海及中国大陆的主要水汽输送源均发生了明显变化，来自于孟加拉湾和热带印度洋的水汽输送到南海后，再从南海输送到中国大陆。而季风的活动同时也制约了强水汽辐合带的出现，其在低纬的维持为雨带长期稳定于南方地区提供了有利条件。     

A possible role of solar radiation and ocean in the mid-Holocene East Asian monsoon climate

An atmospheric general circulation model (AGCM) and an oceanic general circulation model (OGCM) are asynchronously coupled to simulate the climate of the mid-Holocene period. The role of the solar radiation and ocean in the mid-Holocene East Asian monsoon climate is analyzed and some mechanisms are revealed. At the forcing of changed solar radiation induced by the changed orbital parameters and the changed SST simulated by the OGCM, compared with when there is orbital forcing alone, there is more precipitation and the monsoon is stronger in the summer of East Asia, and the winter temperature increases over China. These agree better with the reconstructed data. It is revealed that the change of solar radiation can displace northward the ITCZ and the East Asia subtropical jet, which bring more precipitation over the south of Tibet and North and Northeast China. By analyzing the summer meridional latent heat transport, it is found that the influence of solar radiation change is mainly to increase the convergence of atmosphere toward the land, and the influence of SST change is mainly to transport more moisture to the sea surface atmosphere. Their synergistic effect on East Asian precipitation is much stronger than the sum of their respective effects.     

ROLE OF A WARM AND WET TRANSPORT CONVEYOR OF ASIAN SUMMER MONSOON IN A BEIJING HEAVY RAINSTORM ON JULY 21, 2012

A heavy rainstorm named Beijing “7.21” heavy rainstorm hit Beijing on 21 to 22 July 2012, which is recorded as the most severe rainstorm since 1951. The daily precipitation amount in many stations in Beijing has broken the history record. Based on the NCAR/NCEP reanalysis data and precipitation observation,the large-scale conditions which caused the “7.21” heavy rainstorm are investigated, with the emphasis on the relationship between it and an equatorial convergence zone, Asian summer monsoon as well as the tropical cyclone over the ocean from the Philippines to the South China Sea (SCS). The results indicated that a great deal of southerly warm and wet moisture carried by northward migrating Asian summer monsoon provided plenty of moisture supplying for the “7.21” heavy rainstorm. When the warm and wet moisture met with the strong cold temperature advection induced by cold troughs or vortexes, an obviously unstable stratification formed, thus leading to the occurrence of heavy precipitation. Without this kind of intense moisture transport, the rainstorm only relying on the role of the cold air from mid- and higher- latitudes could not reach the record-breaking intensity. Further research suggested that the northward movement of an Asian monsoonal warm and wet moisture transport conveyor (MWWTC) was closely related with the active phase of a 30-60 day intra-seasonal oscillation of the Asian summer monsoon. During this time, the monsoon surge triggered and maintained the northward movement of the MWWTC. In addition, compared with another heavy rainstorm named “63.8” heavy rainstorm, which occurred over the Huaihe River Basin in the mid-August 1963 and seriously affected North China, a similar MWWTC was also observed. It was just the intense interaction of the MWWTC with strong cold air from the north that caused this severe rain storm.     

Effects of intraseasonal oscillation on the anomalous East Asian summer monsoon during 1999

The 1999 East Asian summer monsoon was very unusual for its weak northward advance and remarkably anomalous climate conditions. The monsoonal southwesterly airflow and related rain belt in East Asia were blocked south of the Yangtze River Valley. The monsoonal airflow and major moisture transport conduct shifted eastward and turned northward to Japan from the tropical western Pacific rather than to East China from the South China Sea （SCS） as in normal years. Severe and prolonged drought occurred over extensive areas of North China and heavy precipitation in South China and Japan. The investigation on the possible intrinsic mechanisms related to such an anomalous monsoon year has shown that the unique behavior of intraseasonal oscillation may play an essential role during this process. During this year, the northward propagation of 30-60-day anomalous low-level cyclone/anticyclone collapsed in the region around 20°N and did not extend beyond the latitudes of the Yangtze River basin due to the barrier of strong cold air intrusion from the mid-latitudes. The southwesterly moisture flux on the northwestern flank of the anticyclonic moisture transport system in the western North Pacific, which was regulated by the northward shift of 30-60-day cyclonic/anticyclonic moisture transport, also did not reach the region north of 30°N as well. Under this circumstance, the weak northward advance of the monsoon westerlies and associated northward moisture transport could not arrive in North China and led to the severe droughts there in 1999. The SCS and South China were mostly affected by the airflow in the southern and northern flanks of the same 30-60-day cyclones or anticyclones, respectively, and thus controlled by the nearly reverse zonal wind and moisture convergent/divergent conditions. The rainfall in the SCS and South China showed out-of-phase oscillation through the transient local Hadley circulation, with the rainfall maximum occurring in the SCS （South China） when the 30-60-day anticyclone （cyclone） r     

2020年夏季我国气候异常特征及成因分析

2020年夏季我国天气气候极为异常,全国平均降水量为373.0 mm,较常年同期偏多14.7%,为1961年以来次多;季节内阶段性特征显著,6—7月多雨带主要位于江南大部—江淮地区,8月则主要在东北、华北及西南地区,致使2020年夏季雨型分布异常,不是传统认识上的四类雨型分布。通过对同期大气环流和热带海温等异常特征分析发现,6—7月,欧亚中高纬环流表现为“两脊一槽”型,东亚副热带夏季风异常偏弱,西太平洋副热带高压(以下简称西太副高)较常年同期显著偏强、偏西,第一次季节性北跳偏早,第二次北跳明显偏晚,且表现出明显的准双周振荡特征;使得来自西北太平洋的转向水汽输送偏强,并与中高纬不断南下的冷空气活动相配合,水汽通量异常辐合区主要位于长江中下游地区,导致江淮梅雨异常偏多。热带印度洋持续偏暖对维持6—7月西太副高偏强偏西及东亚夏季风异常偏弱起到了重要作用。8月,欧亚中高纬环流调整为“两槽一脊”型,蒙古低压活跃;西太副高也由前期偏纬向型的带状分布转为“块状”分布,脊线位置偏北;沿西太副高外围的异常西南风水汽输送延伸至华北—东北南部,形成自西南到东北的异常多雨带,与6—7月江淮流域降水异常偏多的空间分布有明显不同。异常的热带大气季节内振荡活动是导致8月中低纬大气环流发生调整的重要原因。     

青藏高原热力强迫对中国东部降水和水汽输送的调制作用

从4个方面综述了有关青藏高原大地形热力“驱动”对中国东部雨带和水汽输送特征及其年代际变化的影响作用的研究进展:(1)中国三阶梯大地形热力过程变化与季风雨带季节演进;(2) 青藏高原地-气过程热力“驱动”及其季风水汽输送结构;(3) 青藏高原积雪冷源对中国东部水汽输送结构及其雨带分布的影响;(4) 青藏高原视热源变化与雨带年代际变化相关特征及其可能调制。其主要研究结论是:(1)中国西部高原特殊三阶梯大地形结构强化了海-陆热力差异,尤其是高原大地形使地-气热力差异季节变化有由青藏高原向东北方向大地形区域延伸变化趋势,且其与季风雨带由东南沿海移向西北朝青藏高原与黄土高原边缘同步演进,两者似乎存在类似季节内演进的一种“动态的吸引”。(2)中国东部雨带时空变化特征和季风强弱变化趋势均与青藏高原热源强弱异常变化相对应。青藏高原热源异常影响低纬度海洋向陆地的水汽传输路径和强度,进而调制中国东部降水时空演变。在青藏高原热源强和弱年,中国降水变率空间分布特征分别为“北涝南旱”和“南涝北旱”。青藏高原视热源强(弱)异常变化“强信号”将对东亚与南亚区域的季风水汽输送结构,以及夏季风降水时空分布的变异具有“前兆性”的指示意义。(3)长江中下游地区作为独特南北两支水汽流的汇合带,该地区夏季青藏高原热源与水汽通量相关矢特征呈类似于青藏高原多雪与少雪年水汽通量偏差场中水汽汇合区显著特征差异,揭示了冬季青藏高原积雪冷源影响中国东部夏季长江流域梅雨水汽输送结构特征。(4)中国降水的年代际变化基本型态为中国东部呈“南涝北旱趋势”,西北区域呈现出“西部转湿趋势”。但基于近10年青藏高原春季视热源出现“降后回升”趋势,中国东部“南涝北旱”的降水格局已出现转折趋势。     

2008年梅雨异常大尺度环流成因分析

利用NCEP再分析资料对2008年江淮梅雨异常特征及其大尺度环流成因进行了分析研究。结果表明： （1）2008年入（出）梅显著偏早、 梅雨期长度略偏短, 梅雨分布呈南涝北旱、 东多西少, 梅雨量偏少、 强度偏弱。（2）该年入梅显著偏早是东亚大气环流由冬季型向夏季型转换提前所致, 副热带高空西风急流北跳、 500 hPa西风带环流调整、 西太平洋副热带高压季节性北跳、 夏季风北涌至江淮流域的时间均早于常年。（3）该年出梅显著偏早的主导因素是冷空气活动。（4）南涝北旱梅雨型是受南亚高压东段脊线位置接近常年、 副热带高压脊线处于适宜梅雨发生纬度带的南段、 低空西南急流和水汽输送带北缘位置以及高空强辐散和中低空强辐合区位置偏南的影响。（5）东多西少梅雨型是冷空气路径偏西所致。（6）梅雨期夏季风北涌至江淮流域活动次数偏少是梅雨量偏少的重要因素。     

用过程透雨量确定的东亚夏季风北边缘特征

利用1951—2006年全国715个站逐日降水资料及NCEP/NCAR逐日和月平均再分析资料, 以农作物生长角度为出发点, 采用过程透雨量 (20 mm) 标准确定4—10月出现6次及6次以上过程透雨量作为东亚夏季风区, 以北边缘历年波动范围确定夏季风边缘带, 根据连续透雨过程达到无旱标准来判断东亚夏季风的开始时间。主要分析了夏季风北边缘的年际、年代际变化特征和夏季风边缘带的变化范围以及夏季风边缘的推进过程和北边缘变化机制及其对我国降水的影响。结果表明:透雨标准较好地确定了边缘带位置, 夏季风北边缘呈现向南偏移的趋势, 边缘带范围有所扩大; 北边缘变化与偏南风强弱和水汽输送联系紧密, 并且对我国雨带的分布以及北方降水有一定影响, 北边缘偏北, 雨带偏北, 则华北降水偏多。     

论东亚夏季风的特征、驱动力与年代际变化

本文是以新的资料和研究结果对东亚夏季风的基本特征、驱动力和年代际变化所作的重新分析与评估。内容包括四个部分:（1）东亚夏季风的基本特征;（2）东亚夏季风的驱动力;（3）东亚夏季风的年代际变率与原因;（4）东亚夏季风与全球季风的关系。结果表明:东亚夏季风是亚洲夏季风的一个重要有机部分,主要由来源于热带的季风气流组成,并随季节由南向北呈阶段性推进,它是形成夏季东亚天气与气候的主要环流和降水系统。驱动夏季风的主要强迫有三部分:外部强迫、耦合强迫与内部变率,其中人类活动引起的外强迫（气候变暖、城市化、气溶胶增加等）是新出现的外强迫,它正不断改变着东亚夏季风的特征与演变趋势。海洋与陆面耦合强迫作为自然因子是引起东亚夏季风年际和年代际变化的主要原因,其中太平洋年代尺度振荡（PDO）与北大西洋多年代尺度振荡（AMO）的协同作用是造成东亚夏季风30~40年周期振荡的主要原因。1960年代以后,东亚夏季风经历了强—弱—强的年代际变化,相应的中国东部夏季降水型出现了“北多南少”向“南涝北旱”以及“北方渐增”的转变。最近的研究表明,上述东亚夏季风年代际变化与整个亚非夏季风系统的变化趋势是一致的。在本世纪主要受气候变暖的影响,夏季风雨带将持续北移,中国北方和西部地区出现持续性多雨的格局。最后本文指出,亚非夏季风系统相比于其他区域季风系统更适合全球季风的概念。     

亚洲夏季风的年际和年代际变化及其未来预测

本文是对我们近五年在亚洲夏季风年代际与年际变率及其未来预测方面研究的一个综述.主要包括下列三个问题:(1)根据123年中国夏季降水资料和印度学者的分析,检测出亚洲夏季风具有明显的年代际尺度减弱,这种年代际变化使中国东部(包括东亚)和南亚夏季降水的格局在过去60年中发生了明显变化.在东亚,从1970年代后期开始,主要异常雨带有不断南移的趋势,结果造成了南涝北旱的降水分布,这主要受到60～80年年代际振荡的影响.青藏高原前冬和春季积雪的年代际减少与热带中东太平洋海表温度的年代际增加是东亚降水型改变的主要原因,这是通过减弱亚洲地区夏季海陆温差与夏季风强度而实现的.未来亚洲夏季风的预测表明,东亚夏季风和南亚夏季风对气候变暖有十分不同的响应.东亚夏季风在本世纪将增强,雨带北推,尤其在2040年代之后;而南亚夏季风环流将继续减弱.这种不同的变化是由于两者对高低层海陆热力差异的不同响应造成.(2)年际尺度的变率在亚洲夏季风区主要表现为2年与4～7年的振荡.本文着重分析了2年振荡(TBO)形成的过程、机理及其对东亚降水的影响.对TBO-海洋机理进行了具体的改进,说明了东亚夏季风降水深受TBO影响的原因,尤其是阐明了长江型(YRV) TBO和淮河型(HRV) TBO的特征及其形成的循环过程.(3)在总结亚洲夏季风时期遥相关型的基础上,本文提出了季节内和年际尺度的低空遥相关型:即西北太平洋季风的遥相关型与印度“南支”和“北支”遥相关型.它们基本上反映了沿低空夏季风强风速带Rossby波群速度传播的结果.据此可以根据西北太平洋和印度夏季风的变化分别预测中国梅雨和华北雨季来临和降水异常.最后研究还表明,在本世纪亚洲夏季风可能更显著地受到人类活动造成的全球变暖的影响,未来的亚洲夏季风活动是人类排放的CO2引起的全球变暖与自然变化(海洋和陆面过程(积雪))共同作用的结果.     

A STUDY ON THE RELATIONSHIP BETWEEN SPRING SOIL MOISTURE OVER CHINA AND EAST ASIA SUMMER MONSOON

The correlation analysis has been used to study the relationship between spring soil moisture over China and East Asian summer monsoon (EASM). It is shown that EASM has a strong positive correlation with spring soil moisture over southwest China and the Great Bend region of the Yellow River. A standard soil moisture index (SMI) has been defined using the observed soil moisture of the two regions. The results show that SMI has a strong correlation with EASM. The years of strong (weak) SMI are associated with stronger (weaker) summer monsoon circulation. In the years of strong SMI, the west Pacific subtropical high is much northward in position and weaker in intensity; the westerlies zone is also more to the north. All of these make EASM circulation move northward and cause the rainfall belt to relocate to North China and Northeast China. SMI can reflect the variation of the summer rainfall anomaly over eastern China. In the years of strong SMI, the rainfall belt is mainly located over the northem part of China.However, during the weak years, the summer rainfall belt is largely located over the mid- and lower- reaches of the Yangtze River. Additionally, the SMI has obvious oscillations of quasi 4-6 years and quasi 2 years. Moreover, negative SMI predicts EASM better than positive SMI.     

Influence of soil moisture in eastern China on the East Asian summer monsoon

The sensitivity of the East Asian summer monsoon to soil moisture anomalies over China was investigated based on ensembles of seasonal simulations(March–September) using the NCEP GCM coupled with the Simplified Simple Biosphere Model(NCEP GCM/SSi B). After a control experiment with free-running soil moisture, two ensembles were performed in which the soil moisture over the vast region from the lower and middle reaches of the Yangtze River valley to North China(YRNC) was double and half that in the control, with the maximum less than the field capacity. The simulation results showed significant sensitivity of the East Asian summer monsoon to wet soil in YRNC. The wetter soil was associated with increased surface latent heat flux and reduced surface sensible heat flux. In turn, these changes resulted in a wetter and colder local land surface and reduced land–sea temperature gradients, corresponding to a weakened East Asian monsoon circulation in an anomalous anticyclone over southeastern China, and a strengthened East Asian trough southward over Northeast China. Consequently, less precipitation appeared over southeastern China and North China and more rainfall over Northeast China. The weakened monsoon circulation and strengthened East Asian trough was accompanied by the convergence of abnormal northerly and southerly flow over the Yangtze River valley, resulting in more rainfall in this region.In the drier soil experiments, less precipitation appeared over YRNC. The East Asian monsoon circulation seems to show little sensitivity to dry soil anomalies in NCEP GCM/SSi B.     

2012年我国夏季降水预测与异常成因分析

本文对2012年我国夏季降水的实况和预测进行简要回顾,发现2012年夏季降水大体呈北方涝、长江旱的分布,主雨带位于黄河流域及其以北,降水异常偏多的区域主要位于西北大部、内蒙古和环渤海湾,黄淮与江淮地区降水偏少,江汉至淮河上游一带干旱严重;预测的主雨带位于华北南部至淮河,较实况偏南。对我国北方降水异常偏多的成因分析表明:2012年夏季欧亚中高纬地区阻塞高压（简称阻高）强盛,同时东北冷涡活动频繁,中高纬500 hPa高度场从西至东呈“+-+”的分布,这种环流形势没有造成长江洪涝是因为东亚夏季风异常偏强,同时西太平洋副热带高压（副高）偏北,冷暖空气对峙于我国北方地区,导致北方降水异常偏多。分析还表明阻高、东北冷涡、东亚夏季风和副高这四个系统的不同配置影响着冷暖气流的对峙位置,进而形成我国夏季的主雨带。最后通过定量和定性判断相结合的方法,选取了2012年夏季降水的最佳相似年和最佳相反年,对比分析了2012年夏季降水与其最佳相似年和最佳相反年的海温演变与东亚夏季风环流系统主要成员的差异:1959年夏季降水作为2012年夏季降水的最佳相似年,虽然海温及东亚夏季风系统关键成员异常不明显,但是和2012年也呈近似相反的特征;而1980年夏季降水作为2012年夏季降水的最佳相反年,海温及东亚夏季风环流系统关键成员和2012年呈显著的反向特征,这些观测事实反映了我国夏季降水与海温及东亚夏季风环流系统关键成员这些主要影响因子之间关系的年代际变化。     

Multi-year simulation of the East Asian Monsoon and Precipitation in China using a Regional Climate Model and Evaluation

1. Introduction As an important way to study the global climate change, because of its low resolution, GCM (general circulation model) shows obvious deficiency and uncer- tainty in capturing some regional features when used in the regional climate study, and the uncertainty is even serious in regional climate simulation over East Asia (Ding et al., 2000; Zhao and Luo, 1998; Qian et al., 1999). The high-resolution regional climate model (RegCM) developed in the 1980s can provide better simu…     

高原夏季风指数的定义及其特征分析

基于1958~2002年ECMWF再分析资料,我国160个台站降水和气温资料,从夏季高原季风环流系统特点出发,定义了能较好表征高原夏季风环流变化的特征指数,分析了高原夏季风年际、年代际变化特征,并揭示了高原夏季风强弱异常时的环流特征及其与中国夏季降水和气温的关系,主要结论为:(1)用6~8月600hPa (27.5~30°N,80~100°E)范围内平均的西风分量距平与(35~37.5°N,80~100°E)范围内平均的东风分量距平差定义了高原夏季风指数(PM I)。该指数计算简单,意义清楚,代表性好。(2)1958~2002年高原夏季风整体呈增强趋势,在20世纪60年代中期之前是高原夏季风的强盛期,之后是高原夏季风弱期,在80年代以后又转为季风强期。(3)高原夏季风与中国夏季降水和气温相关很好。将该指数与之前汤懋苍定义的指数进行性能综合比较后,发现该指数对川渝地区的夏季降水及气温有更好的指示意义。