Impact of Ocean-Continent Distribution over Southern Asia on the Formation of Summer Monsoon

Using the CCM3/NCAR, a series of numerical experiments are designed to explore the effect of ocean-land interlaced distributions of Africa-Arabian Sea-India Peninsula-Bay of Bengal (BOB)-Indo-China Peninsula-South China Sea on the formation of the Asian summer monsoon circulation (ASMC). The results show that the thermal difference between African or Indian Subcontinent and nearby areas including the Indian Ocean, Arabian Sea, and part of BOB is the primary mechanism that maintains the Indian monsoon circulation. In the experiment getting rid of these two continents, the Indian monsoon system (IMS) members, i.e., the Somali cross-equatorial jet (40°E) and the southwesterly monsoon over the Arabian Sea and BOB, almost disappear. Moreover, the Hadley circulation weakens dominantly. It also proves that Africa has greater effect than Indian Subcontinent on the IMS. However, the existence of Indo-China Peninsula and Australia strengthens the East Asian monsoon system (EAMS). The thermal contrast between Indo-China Peninsula and SCS, Australia and western Pacific Ocean plays an important role in the formation of the tropical monsoon to the south of the EAMS. When the Indo-China Peninsula is masked in the experiment, the cross-equatorial flow (105°E and 125°E) vanishes, so does the southwesterly monsoon usually found over East Asia, and EAMS is enfeebled significantly. In addition, the impacts of these thermal contrasts on the distribution of the summer precipitation and surface temperature are investigated.     

Characteristics of Zonal Propagation of Atmospheric Kinetic Energy at Equatorial Region in Asia

Based on the daily NCEP/NCAR reanalysis dataset from 1980 to 1997, the zonal propagations of 850 hPa kinetic energy (KE) and meridional wind (v) at equatorial region are examined respectively. Results show that the strongest center of KE in the tropical Asian monsoon region is located at 75°-90°E, with the secondary over the Somalia low-level jet channel, i.e., about 50°E. East to 90°E, disturbances of both KE and v observed are mainly coming from the western Pacific Ocean and propagating westward to the Bay of Bengal (BOB) passing through the South China Sea. But the propagation directions of both KE and v are rather disorderly between the BOB and the Somalia jet channel. Therefore, the East Asian summer monsoon and the Indian summer monsoon are different in the propagating features of the disturbances of KE and v. Above facts indicate that East Asian monsoon system exists undoubtedly even at the equatorial region, and quite distinct from the Indian monsoon system, it is mainly affected by the disturbances coming from the tropical western Pacific rather than from the Indian monsoon region. The boundary of the two monsoon systems is around 95°-100°E, which is more westward than the counterpart as proposed in earlier studies by 5-10 degrees in longitude.     

EFFECT OF THE INDIAN PENINSULA ON THE COURSE OF THE ASIAN TROPICAL SUMMER MONSOON*

In terms of the NCAR Community Climate Model (CCM3),the effect of the Indian Peninsula on the course of the Asian tropical summer monsoon is simulated in this paper,and numerical experimental results show that the Indian Peninsula plays a critical role in the establishment process of the Asian tropical summer monsoon.When the CCM3 includes the Indian Peninsula,the model successfully simulates out the course of the Asian tropical summer monsoon,i.e.the South China Sea (SCS) summer monsoon at first bursts in middle May,while the Indian monsoon just establishes until middle June.However when the Indian Peninsula topography is deleted in the model,the Indian and SCS summer monsoons almost simultaneously establish in late May.Numerical results further indicate that in the former experiment the sensible heating of the Indian Peninsula warms the air above and produces evident temperature contrast between the peninsula and its adjacent SCS and Bay of Bengal (BOB).which results in the strengthening and maintenance of the BOB trough in the low-middle layer of the troposphere in the end of spring and early summer and thus the earliest establishment of the Asian tropical summer monsoon in the SCS in middle May.However,the Indian summer monsoon just establishes until middle June when the strong west wind over the Arabian Sea shifts northwards and cancels out the influence of the northwest flow behind the BOB trough.In the latter experiment the effect of Tibetan Plateau only produces a very weak BOB trough,and thus the SCS and Indian summer monsoons almost simultaneously establish.     

EFFECT OF THE INDIAN PENINSULA ON THE COURSE OF THE ASIAN TROPICAL SUMMER MONSOON

In terms of the NCAR Community Climate Model (CCM3),the effect of the Indian Peninsulaon the course of the Asian tropical summer monsoon is simulated in this paper,and numericalexperimental results show that the Indian Peninsula plays a critical role in the establishmentprocess of the Asian tropical summer monsoon.When the CCM3 includes the Indian Peninsula,the model successfully simulates out the course of the Asian tropical summer monsoon,i.e.theSouth China Sea (SCS) summer monsoon at first bursts in middle May,while the Indian monsoonjust establishes until middle June.However when the Indian Peninsula topography is deleted in themodel,the Indian and SCS summer monsoons almost simultaneously establish in late May.Numerical results further indicate that in the former experiment the sensible heating of the IndianPeninsula warms the air above and produces evident temperature contrast between the peninsulaand its adjacent SCS and Bay of Bengal (BOB).which results in the strengthening and maintenanceof the BOB trough in the low-middle layer of the troposphere in the end of spring and early summerand thus the earliest establishment of the Asian tropical summer monsoon in the SCS in middleMay.However,the Indian summer monsoon just establishes until middle June when the strongwest wind over the Arabian Sea shifts northwards and cancels out the influence of the northwestflow behind the BOB trough.In the latter experiment the effect of Tibetan Plateau only produces avery weak BOB trough,and thus the SCS and Indian summer monsoons almost simultaneouslyestablish.     

热带大气ISO在几种再分析资料中的对比分析

利用NCEP/NCAR, NCEP/DOE和ERA40 3套再分析资料的逐日200 hPa纬向风数据,选取1961—1990年、1971—2000年和1981—2010年3种不同气候态,对比分析了3种气候态下热带大气季节内振荡 (ISO) 的基本气候特征及其在不同再分析资料中的异同。研究表明:1981—2010年气候态下,热带大气ISO冬春强、夏秋弱的年循环特征更加明显,东传短波能量增强,起始北传时间偏晚。NCEP/NCAR与NCEP/DOE资料所表征的热带大气ISO在空间分布、强度和能量传播方面的一致性较好。NCEP/NCAR资料反映的热带大气ISO强度在热带印度洋和热带西太平洋地区较ERA40资料偏弱,在赤道东太平洋地区较ERA40资料偏强;ERA40资料反映的热带大气ISO强度在12月—次年3月中旬较NCEP/NCAR资料偏强,而在3月中旬—11月偏弱;ERA40资料反映的热带大气ISO振荡位相较NCEP/NCAR资料超前10 d左右;NCEP/NCAR资料反映的东传谱能量弱于ERA40资料,西传能量强于ERA40资料;7月中旬,NCEP/NCAR资料反映的东亚地区大气ISO经向北传较ERA40资料偏晚。     

青藏高原前期冬春季地面热源与我国夏季降水关系的初步分析

首先对青藏高原地表热通量再分析资料与自动气象站(AWS)实测资料进行对比, 结果表明: 相对于美国国家环境预报中心和国家大气中心20世纪90年代研制的NCEP/NCAR(Kalnay 等1996)和NCEP/DOE (Kanamitsu 等2002) 再分析资料, ECMWF(Uppala 等2004)资料在高原地区的地表热通量具有较好的代表性。进一步利用奇异值分解(SVD)方法分析了ECMWF资料反映的高原地面热源与我国夏季降水的关系, 发现前期青藏高原主体的冬季地面热源与长江中下游地区夏季降水量呈负相关, 与华北和东南沿海地区的夏季降水量呈正相关。而长江中下游地区夏季降水量还与春季高原南部的地面热源存在负相关、与高原北部的地面热源存在正相关。高原冬、春季地面热源场的变化是影响我国夏季降水的重要因子。     

基于不同资料的影响南海热带气旋环流背景对比北大核心CSCD

利用1981—2020年中国热带气旋最佳路径数据集、中国大气再分析资料(CMA-RA)、欧洲中期天气预报中心ERA5及美国NCEP/NCAR再分析资料(NCEP-Ⅰ),对比不同资料在表征影响南海热带气旋活动环流背景的能力,探讨CMA-RA的适用性。结果表明:不同资料基本刻画出与热带气旋活动密切相关的环流特征,包括南方涛动、菲律宾至南海低层纬向风、热带低层纬向风反向分布型、菲律宾至南海中东部低层涡度、热带西太平洋垂直风切变及南海至菲律宾以东海域中层湿度。它们对南方涛动、关键区纬向风和中层湿度的刻画较相似,CMA-RA和ERA5对南方涛动、低层纬向风及其与热带气旋关系的描述一致性高,较NCEP-Ⅰ密切,但低层经向风、关键物理量差异较大。对极端年环流具有相似的表现能力,但异常程度存在差异,海平面气压、低层纬向风高度一致,以CMA-RA与ERA5最接近;中层湿度CMA-RA与ERA5接近,较NCEP-Ⅰ偏小;关键物理量差异较大。CMA-RA对南海热带气旋环流的刻画具有与ERA5和NCEP-Ⅰ相当的性能,并与ERA5一致性较高,可为相关工作提供可替换的再分析资料集。     

南海夏季风与印度夏季风爆发早晚的年际差异

利用NCEP/NCAR逐日再分析资料分析了南海夏季风与印度夏季风的爆发时间,根据爆发时间差值区分了差异大小年,结果表明二者的爆发具有明显的年际异常.差异偏小年,南海夏季风爆发时,印度半岛已经盛行偏西风,两者几乎同时建立;而差异偏大年,南海夏季风爆发后7候左右印度才盛行偏西风,印度夏季风爆发得晚,环流形势有明显差异;进一步分析机制表明,印度夏季风的建立主要由经向温度反转所决定,而南海夏季风的建立取决于纬向温度反转,二者的爆发具有相对独立性,且纬向温度反转的早晚更大程度上影响了差异的大小,积温线密集带出现的早晚决定了温度反转的早晚.     

The Earliest Onset Areas and Mechanism of the Tropical Asian Summer Monsoon

The multi-yearly averaged pentad meteorological fields at 850 hPa of the NCEP/NCAR reanalysis dada and the TBB fields of the Japan Meteorological Agency during 1980-1994 are analyzed. It is found that if the pentad is taken as the time unit of the monsoon onset, then the tropical Asian summer monsoon (TASM) onsets earliest, simultaneously and abruptly over the whole area in the Bay of Bengal (BOB), the Indo-China Peninsula (ICP), and the South China Sea (SCS), east of 90°E, in the 27th to 28th pentads of a year (Pentads 3 to 4 in May), while it onsets later in the India Peninsula (IP) and the Arabian Sea (AS), west of 90°E. The TASM bursts first at the south end of the IP in the 30th to 31st pentads near 10°N, and advances gradually northward to the whole area, by the end of June. Analysis of the possible mechanism depicts that the rapid changes of the surface sensible heat flux, air temperature, and pressure in spring and early summer in the middle to high latitudes of the East Asian continent between 100°E and 120癊are crucially responsible for the earliest onset of the TASM in the BOB to the SCS areas. It is their rapid changes that induce a continental depression to form and break through the high system of pressure originally located in the above continental areas. The low depression in turn introduces the southwesterly to come into the BOB to the SCS areas, east of 90°E, and thus makes the SCS summer monsoon (SCSSM) burst out earliest in Asia. In the IP to the AS areas, west of 90°E, the surface sensible heat flux almost does not experience obvious change during April and May, which makes the tropical Indian summer monsoon (TISM) onset later than the SCSSM by about a month. Therefore, it is concluded that the meridian of 90°E is the demarcation line between the South Asian summer monsoon (SASM, i.e., the TISM) and the East Asian summer monsoon (EASM, including the SCSSM). Besides, the temporal relations between the TASM onset and the seasonal variation of the South Asian high (SAH) are discussed, too, and it is found that there are good relations between the monsoon onset time and the SAH center positions. When the SAH center advances to north of 20°N, the SCSSM onsets, and to north of 25°N, the TISM onsets at its south end. Comparison between the onset time such determined and that with other methodologies shows fair consistency in the SCS area and some differences in the IP area.     

华南7月异常温度气候变化研究

采用中国气象局整编的月平均气温资料、NCEP／NGAR再分析资料等,分析了华南7月极端气温的气候变化,并据此探讨了2003年7月华南高温的成因。研究表明：华南7月高、低温年500hPa欧亚环流差异显著;高(低)温年东亚热带夏季风偏弱(强)。华南7月气温异常与我国南海、东海和赤道中东太平洋前冬和夏季的SST及同期南海和西北太平洋的台风活动关系密切。     

印度洋偶极子对中国南海夏季西南季风水汽输送的影响

利用NCEP/NCAR再分析资料和中科院大气物理研究所PIAP3大气环流模式,分析了印度洋偶极子对夏季中国南海西南季风水汽输送的影响。结果表明,印度洋偶极子正位相期间夏季中国南海西南水汽输送较强,负位相期间则较弱。原因可归结为以下:正位相期间,MJO（Madden-Julian Oscillation）多活动于热带西印度洋,其向东传播受到阻碍,但经向传播明显,通常可传播至孟加拉湾地区,同时PIAP3显示印度洋季风槽位置偏北,且印尼以西过赤道气流较强,从而使得这一地区气旋性环流得到建立与加强。孟加拉湾地区对应着较强的对流活动以及深厚积云对流加热,从而通过对流加热的二级热力响应使西太平洋副热带高压位置向北推进,进而使得南海地区西南季风水汽输送得到建立与加强。在此期间孟加拉湾、中南半岛至南海地区对流活动较强,而苏门答腊沿岸对流活动受到抑制,由此增强了Reverse-Hadley环流,使低层经向风较强,进而增强了南海西南季风的水汽输送,PIAP3大气环流模式证实了Reverse-Hadley环流的增强。负位相期间,MJO多活动于热带东印度洋,在东传过程中受到Walker环流配置影响,在140°E赤道附近形成东西向非对称积云对流加热热源,其东侧Kelvin波响应加强了东风异常并配合副热带高压南缘东风压制了中国南海的西南季风水汽输送。在此期间,MJO在南海地区的经向传播较强,但经向传播常止步于南海地区15°N附近,虽携带大量水汽,但深厚积云对流强烈地消耗水汽使大气中水汽含量降低,PIAP3大气环流模式证实负位相期间深厚积云对流对水汽消耗加大,从而使得负位相期间南海地区水汽含量与正位相期间大体相近,但由于经向风不足使水汽向北输送较弱。     

THE WARMING MECHANISM IN THE SOUTHERN ARABIAN SEA DURING THE DEVELOPMENT OF INDIAN OCEAN DIPOLE EVENTS

This study aims to explore the relative role of oceanic dynamics and surface heat fluxes in the warming of southern Arabian Sea and southwest Indian Ocean during the development of Indian Ocean Dipole (IOD) events by using National Center for Environmental Prediction/National Center for Atmospheric Research (NCEP/NCAR) daily reanalysis data and Global Ocean Data Assimilation System (GODAS) monthly mean ocean reanalysis data from 1982 to 2013, based on regression analysis, Empirical Orthogonal Function (EOF) analysis and combined with a 2? layer dynamic upper-ocean model. The results show that during the initial stage of IOD events, warm downwelling Rossby waves excited by an anomalous anticyclone over the west Indian Peninsula, southwest Indian Ocean and southeast Indian Ocean lead to the warming of the mixed layer by reducing entrainment cooling. An anomalous anticyclone over the west Indian Peninsula weakens the wind over the Arabian Sea and Somali coast, which helps decrease the sea surface heat loss and shallow the surface mixed layer, and also contributes to the sea surface temperature (SST) warming in the southern Arabian Sea by inhibiting entrainment. The weakened winds increase the SST along the Somali coast by inhibiting upwelling and zonal advection. The wind and net sea surface heat flux anomalies are not significant over the southwest Indian Ocean. During the antecedent stage of IOD events, the warming of the southern Arabian Sea is closely connected with the reduction of entrainment cooling caused by the Rossby waves and the weakened wind. With the appearance of an equatorial easterly wind anomaly, the warming of the southwest Indian Ocean is not only driven by weaker entrainment cooling caused by the Rossby waves, but also by the meridional heat transport carried by Ekman flow. The anomalous sea surface heat flux plays a key role to damp the warming of the west pole of the IOD.     

热带印度洋夏季水汽输送特征及对南亚季风区降水的影响

利用NCEP/NCAR再分析环流资料、CMAP降水量和NOAA海温资料研究了热带印度洋夏季水汽输送的时空变化特征,并考察其对南亚季风区夏季降水的影响.热带印度洋夏季异常水汽输送第一模态表现为异常水汽从南海向西到达孟加拉湾后分成两支,其中一支继续往西到达印度次大陆和阿拉伯海,对应印度半岛南端和中南半岛的西风水汽输送减弱,导致这些区域降水减少;第二模态表现为异常水汽从赤道东印度洋沿赤道西印度洋、阿拉伯海、印度半岛、中南半岛的反气旋输送,印度和孟加拉湾南部为反气旋异常水汽输送,水汽辐散、降水减少,而印度东北部为气旋性水汽输送,水汽辐合、降水增多.就水汽输送与局地海温的关系而言,水汽输送第一模态与热带印度洋海温整体增暖关系密切,而第二模态与同期印度洋偶极子关系密切.     

水汽输送对云南夏季风爆发及初夏降水异常的影响

主要利用1961～2000年云南120个站的逐日降水资料和NCEP/NCAR再分析资料,研究水汽输送对云南夏季风爆发和初夏5月降水异常的影响.结果表明,5月份云南上空为一致的西南风水汽输送,主要由来自印度半岛北部的副热带西风水汽输送和热带印度洋至孟加拉湾的西南风水汽输送汇合而成,而来自南海地区西太平洋副高西侧转向的偏南水汽输送是构成云南东部地区水汽输送的重要分支.5月下旬云南夏季风爆发期间,热带印度洋至孟加拉湾地区的水汽输送显著增强,云南上空增湿明显,这为季风爆发提供了必要的水汽条件,而东亚中纬地区冷空气的入侵则可能是触发季风降水的重要机制.进一步研究发现,云南5月降水量显著的年际变化也与大尺度水汽输送异常密切相关,即当热带印度洋至孟加拉湾地区的水汽输送强,而南海至东亚大陆地区的水汽输送弱时,降水量偏多,反之偏少.     

孟加拉湾深对流加热对东亚季风环流系统的影响

利用40年逐日NCEP/NCAR再分析资料、ReynoldsSST资料和R42L9GOALS模式,研究孟加拉湾深对流加热对东亚副热带季风环流系统的影响及其与ENSO的关系。结果表明:孟加拉湾东岸季风于26候开始爆发,其深对流加热的旋转经验正交函数(REOF)分析表明,其激发的东传Rossby波在中高纬度地区具有相当正压结构。数值试验证实孟加拉湾降水增多,其东侧南海到长江以南区域降水明显减少。分析发现季风环流强度指数极小值和Walker环流强度指数极大值的出现对SSTA转折均具超前性,因此,季风环流的变化对预报ElNino减弱或LaNina结束及SSTA变化趋势具有一定的指示意义。     

The East Asian summer monsoon: an overview

Summary The present paper provides an overview of major problems of the East Asian summer monsoon. The summer monsoon system over East Asia (including the South China Sea (SCS)) cannot be just thought of as the eastward and northward extension of the Indian monsoon. Numerous studies have well documented that the huge Asian summer monsoon system can be divided into two subsystems: the Indian and the East Asian monsoon system which are to a greater extent independent of each other and, at the same time, interact with each other. In this context, the major findings made in recent two decades are summarized below: (1) The earliest onset of the Asian summer monsoon occurs in most of cases in the central and southern Indochina Peninsula. The onset is preceded by development of a BOB (Bay of Bengal) cyclone, the rapid acceleration of low-level westerlies and significant increase of convective activity in both areal extent and intensity in the tropical East Indian Ocean and the Bay of Bengal. (2) The seasonal march of the East Asian summer monsoon displays a distinct stepwise northward and northeastward advance, with two abrupt northward jumps and three stationary periods. The monsoon rain commences over the region from the Indochina Peninsula-the SCS-Philippines during the period from early May to mid-May, then it extends abruptly to the Yangtze River Basin, and western and southern Japan, and the southwestern Philippine Sea in early to mid-June and finally penetrates to North China, Korea and part of Japan, and the topical western West Pacific. (3) After the onset of the Asian summer monsoon, the moisture transport coming from Indochina Peninsula and the South China Sea plays a crucial “switch” role in moisture supply for precipitation in East Asia, thus leading to a dramatic change in climate regime in East Asia and even more remote areas through teleconnection. (4) The East Asian summer monsoon and related seasonal rain belts assumes significant variability at intraseasonal, interannual and interdecadal time scales. Their interaction, i.e., phase locking and in-phase or out-phase superimposing, can to a greater extent control the behaviors of the East Asian summer monsoon and produce unique rythem and singularities. (5) Two external forcing i.e., Pacific and Indian Ocean SSTs and the snow cover in the Eurasia and the Tibetan Plateau, are believed to be primary contributing factors to the activity of the East Asian summer monsoon. However, the internal variability of the atmospheric circulation is also very important. In particular, the blocking highs in mid-and high latitudes of Eurasian continents and the subtropical high over the western North Pacific play a more important role which is quite different from the condition for the South Asian monsoon. The later is of tropical monsoon nature while the former is of hybrid nature of tropical and subtropical monsoon with intense impact from mid-and high latitudes.     

温室气体对亚洲夏季风影响的数值研究

利用NCEP/NCAR再分析资料检验全球气候模式CAM5.1模拟亚洲夏季风的能力,CAM5.1模式能够较好再现亚洲夏季风的基本特征。通过工业革命前（1850年）、工业革命后（2000年）温室气体排放情景的敏感性试验探讨近现代温室气体增加对亚洲夏季风的影响机制。结果显示：温室气体增加导致亚洲大部分区域地面气温增加,印度半岛中部、中南半岛和中国东部地区夏季风增强,印度半岛中部及北部、中南半岛中北部和中国东部地区夏季降水增加。分析大气能量收支和转换发现,温室气体增加通过增强大气对流凝结潜热释放的方式加强大气热源;夏季陆地为暖区,不均匀加热引起全位能增加,从而增强全位能向辐散风动能的转换和辐散风动能向无辐散风动能的转换,最终导致这些区域夏季风增强。其中,对流凝结潜热增加是温室气体增加造成大气稳定度降低、对流活动加强、对流云厚度加大、对流降水增加的结果;同时,对流降水增加是总降水增加的主要原因。     

近四十年我国气候变化的初步分析

利用NCEP/NCAR（National Centers for Environmental Prediction/National Center for Atmospheric Research）2001-2010年再分析资料,检验了全球气候系统模式CESM中大气模块CAM（Community Atmosphere Model）对亚洲夏季风和大气热源的模拟能力。结果显示,模式可以再现亚洲夏季风和大气热源的主要特征。通过敏感试验探讨人为气溶胶影响亚洲夏季风的机理,分析、讨论了气溶胶引起的非均匀加热的变化对辐散风和无辐散风强度的影响,在机理上解释了亚洲夏季风减弱的原因。结果表明,人为气溶胶浓度的升高使东亚夏季风强度在中国东南地区、中南半岛北部和印度半岛北部减弱。而中国东南部季风的减弱促使中国内陆降水减少,沿海降水增多。进一步分析人为气溶胶浓度升高的作用发现,其改变了大气热源的分布,造成阿拉伯海、孟加拉湾和中国南海大气热源增强,中国东部地区和中南半岛大气热源减弱,其中气溶胶通过影响凝结潜热来改变大气热源,主要是对对流过程的影响。此外,大气热源分布的变化改变了季风区的热力结构,使中国东南地区、中南半岛北部的加热减弱,从而减少了全位能的产生,使得全位能向辐散风的转换减小,辐散风减弱;同时,中国东南部、中南半岛北部季风由于辐散风向无辐散风转换的减弱,无辐散风减弱,最终导致了夏季风强度的减弱。而且,人为气溶胶对亚洲夏季风的影响主要通过大气热力和动力过程的响应产生作用。     

EFFECTS OF ENSO ON THE RELATIONSHIP BETWEEN IOD AND SUMMER RAINFALL IN CHINA

Based on the data of 1950 – 1999 monthly global SST from Hadley Center, NCAR/NCEP reanalysis data and rainfall over 160 weather stations in China, investigation is conducted into the difference of summer rainfall in China (hereafter referred to as the “CS rainfall”) between the years with the Indian Ocean Dipole (IOD) occurring independently and those with IOD occurring along with ENSO so as to study the effects of El Ni?o - Southern Oscillation (ENSO) on the relationship between IOD and the CS rainfall. It is shown that CS rainfall will be more than normal in South China (centered in Hunan province) in the years of positive IOD occurring independently; the CS rainfall will be less (more) than normal in North China (Southeast China) in the years of positive IOD occurring together with ENSO. The effect of ENSO is offsetting (enhancing) the relationship between IOD and summer rainfall in Southwest China, the region joining the Yangtze River basin with the Huaihe River basin (hereafter referred to as the “Yangtze-Huaihe basin”) and North China (Southeast China). The circulation field is also examined for preliminary causes of such an influence.     

亚洲和南半球大气热源（汇）对亚洲夏季风影响的数值试验

利用NCAR CAM3.1模式及NCEP/NCAR (version 1)再分析资料计算出来的几种大气热源分布情况,分别讨论亚洲各地区和南半球上空夏季大气加热场(热源或冷源)对东亚季风环流系统和印度季风环流系统形成的影响.结果表明:(1)东亚地区上空的大气热源和澳大利亚冷源与东亚夏季风环流关系密切,东亚大陆上空及西太平...