东亚季风环流季节转变与亚太热力场之间的联系及其可能机理     

黄娇文  何金海  徐海明  金啟华 《热带气象学报》2016,(6):817-830

利用NCEP/NCAR再分析数据集,CMAP降水资料及Hadley中心海温,进一步对东亚季风环流季节转变与亚太热力场之间的联系及可能机理进行了研究。首先选用250 hPa两个固定关键区的气温,计算全年逐候的亚太纬向热力差指数,结果表明其与赵平等采用各季不同关键区的APO指数高度一致,但该指数(下称APTD指数)可用于确定热力场季节转变的时间点。发现用APTD指数确定的季节转变时间点能表征东亚大气环流冬季型向夏季型的转变,环流的转变特征为:低层大陆冷高压东移人海,低空偏北风转为偏南风;中层东亚大槽东移减弱,副热带高压单体在菲律宾附近出现,中心显著加强;高层南亚高压从菲律宾以东移到中南半岛西部,西风急流和东风急流发生北跳,高空偏南风转为偏北风。大气环流场的季节转变和热力场联系紧密的可能机理是:在亚太热力场转变的背景下,低空南风的出现,首先改变经向风的垂直切变,触发垂直运动释放潜热,加快冬季加热型向夏季型转变,而夏季加热型又进一步推进环流的调整,促进低空南风高空北风的形成与加强,进而通过热力场和环流场的正反馈过程,最终建立起一个低空南风高空北风的季风经圈环流。最后指出该转变点的早晚与热带中东太平洋的海温异常有显著的正相关,这为短期气候预测提供了依据。  相似文献   

冬夏季环流隔季相关的数值试验     

杨辉  陈隽  孙淑清 《大气科学》2005,29(3):396-408

利用海气耦合和大气气候模式研究东亚冬季风异常对夏季环流的影响, 结果表明, 东亚冬季风异常对于后期环流及海洋状态异常都起了很大的作用.一般情况下, 强的冬季风与后期弱的东亚夏季风和较强的南海季风相对应.与强(弱)冬季风异常相关的风应力的改变可以使热带太平洋海温从冬季至夏季呈现La Nina (El Nio)型异常分布.试验得到的由冬季风异常所产生的海洋及夏季环流的变化与实况是相当接近的.在异常的冬季风偏北风分量强迫下, 西太平洋上形成的偏差气旋环流在夏季已不存在, 这时东亚夏季风反而增强.而冬季赤道西风分量所产生的影响, 则在西太平洋上形成显著的偏差气旋环流, 使东亚副热带夏季风减弱, 南海夏季风加强.对于东亚大气环流而言, 与强弱冬季风对应的热带海洋海温异常强迫下, 不仅是冬季, 后期春季和夏季环流的特征都能得到很好的模拟.但是从分区看, 西太平洋暖池区的海温异常比东太平洋更为重要.单纯的热带中东太平洋的海温异常对东亚大气环流的影响主要表现在冬季, 对后期的影响并不十分清楚.整个热带海洋的异常型分布(不论是El Nio还是La Nia)型, 对冬夏季风的影响是重要的, 而单纯的某个地区的海温异常都比它的整体影响要小.从试验结果看, 海温在大尺度冬夏季环流的隔季相关中起了十分重要的作用.  相似文献   

东亚-太平洋地区环流场和热力场由冬向夏转换的过程特征及其可能机制   总被引：3，自引：0，他引：3  

池艳珍  刘丹妮  何金海  祁莉 《高原气象》2013,32(4)

利用NCEP/NCAR逐日再分析资料和青藏高原逐日视热源资料,分析了东亚 太平洋地区对流层热力场和环流场的季节特征.结果表明,东亚-太平洋热力场上呈现出冬、夏半年反向的特征,冬半年热力格局为“西冷东暖”,夏半年则转为“西暖东冷”,冬半年向夏半年的过渡发生在3月底4月初,相应地,我国东部上空视热源也从冷却转为加热.热力场季节转换的同时,对流层各层环流形势也发生了调整:低层大陆冷高压减弱、东移,太平洋副热带高压显著西伸,形成东亚-西太平洋35°N以南一致的南风区;中层西风带发生了长波调整,由冬季“三槽型”向夏季“四槽型”过渡,西风急流减弱、北移;高层反气旋中心史替,我国上空偏南风由偏北风替代.环流的演变自低层向高层推进,下垫面感热加热的季节变化引起了低层环流的调整以及上升运动的发展,与上升运动相伴的凝结潜热释放则增强了东亚上空的热源,进一步加强了“西暖东冷”的热力格局,从而推进中高层环流的演变.环流调整的时间与东亚副热带季风雨带建立的时间一致,因此,由热力场季节变化引起的对流层环流形势的调整可看成是东亚副热带夏季风环流型的建立过程.  相似文献   

南海夏季风爆发与热带海洋海温和大气环流异常变化关系的研究   总被引：12，自引：0，他引：12  

陈永利  白学志  赵永平 《气候与环境研究》2000,5(4):388-399

用合成和相关分析方法及SVD技术研究了南海夏季风爆发早、晚年份4～6月季风建立时期季风环流的异常及其与热带太平洋-印度洋海温的关系。结果表明,南海夏季风爆发与热带大气环流和海温变异密切相关。（1）当热带中、东太平洋—印度洋（主要在西南部）及南海海温低（高）,西太平洋—澳洲邻近海域海温高（低）时,南海夏季风爆发早（晚）。不同区域海温对季风的影响有明显的季节差异,印度洋主要为晚春至初夏（4～6月）,南海为5～6月,而热带太平洋从前冬一直持续到夏季。（2）不同的海温异常产生不同的季风环流型,南海夏季风爆发早、晚年大气环流的异常变化基本相反。南海夏季风的活动主要受印度季风环流变化的影响,与前期冬春季西太副高的强弱及位置变化密切相关。西太副高弱时,南海夏季风爆发早;反之,爆发晚。（3）热带太平洋—印度洋海温异常引起季风环流和Walker环流的异常变化可能是影响南海夏季风爆发早、晚的物理过程。  相似文献   

前期热带太平洋次表层海温异常与东亚夏季风的可能联系          下载免费PDF全文

郭胜利  李锋  葛非 《大气科学学报》2018,41(1):103-112

利用1979—2012年日本气象厅次表层海温资料和NCEP/NCAR再分析资料,分析了前期冬季热带太平洋次表层海温与东亚夏季风的关系,并讨论了其可能机制。结果表明,前期冬季热带太平洋次表层海温与后期东亚夏季风强弱有显著的相关关系。冬季次表层海温呈现东正西负的类El Nio分布型时,夏季副热带高压偏强,西北太平洋地区受反气旋型环流控制,能将大量的水汽输送到长江和淮河流域,有利于水汽在该区域辐合,为夏季降水偏多创造了条件,此时东亚夏季风活动整体偏弱,反之亦然。但类El Nio分布型对东亚夏季气候变化的影响较类La Nia分布型更显著。此外,冬季热带太平洋次表层海温可能通过其自身能够持续性地影响东亚—太平洋地区的大气环流异常,次表层海温随季节变化有明显的发展和移动趋势:冬季西太平洋暖池次表层冷(暖)海温不断堆积,沿温跃层向东传播使得中东太平洋次表层海温逐渐变冷(暖),冷(暖)海温上翻加强使得海表温度异常,进一步影响到西太平洋副热带高压的位置和强度,并在东亚地区形成经向遥相关波列,通过西北太平洋地区异常反气旋(气旋)环流的作用,影响东亚地区大气环流以及气候变化。  相似文献   

不同PDO位相下El Niño发展年和La Niña年东亚夏季风的季节内变化     

张雯  董啸  薛峰 《大气科学》2020,44(2):390-406

基于1957~2017年观测和再分析资料,合成分析了北太平洋年代际振荡(Pacific decadal oscillation,PDO)不同位相下El Ni?o发展年和La Nina年东亚夏季风的环流、降水特征及季节内变化。结果表明,PDO正、负位相作为背景场,分别对El Ni?o发展年、La Nina年东亚夏季风及夏季降水具有加强作用。PDO正位相一方面可增强El Ni?o发展年夏季热带中东太平洋暖海温异常信号,另一方面通过冷海温状态加强中高纬东亚大陆与西北太平洋的环流异常,从而在一定程度上增强了东亚夏季风环流的异常程度;反之,PDO负位相则增强了La Nina年热带海气相互作用以及中高纬环流(如东北亚反气旋)的异常。在季节内变化方面,El Ni?o发展年6月贝湖以东反气旋性环流为东亚地区带来稳定的北风异常,东北亚位势高度减弱;7月开始,环流形势发生调整,日本以东洋面出现气旋性异常,东亚大陆偏北风及位势高度负异常均得到加强;8月,随着东亚夏季风季节进程和El Ni?o发展,西太平洋出现气旋性环流异常,东亚副热带位势高度进一步降低,西北太平洋副热带高压(简称副高)明显东退。La Nina年6月异常较弱,主要环流差异自7月西北太平洋为大范围气旋性异常控制开始,东亚-太平洋遥相关型显著,副高于季节内始终偏弱偏东。上述两种情况下,均造成东亚地区夏季降水总体上偏少,尤其是中国北方降水显著偏少。  相似文献   

东亚大气环流由冬向夏的转变时间及其特征   总被引：4，自引：0，他引：4       下载免费PDF全文

何金海  祁莉  刘丹妮  朱占云 《气象科学》2010,30(5):591-596

利用NCEP/NCAR再分析数据集及CMAP降水资料分析了东亚大气环流由冬转夏的可能时间及其特征。结果表明,3月底4月初,东亚与西太平洋对流层纬向热力差异由东暖西冷转为东冷西暖,对流层低层大陆高压东移,使得纬向气压梯度发生逆转。与此同时,对流层低层偏南风建立,经向垂直环流也发生季节逆转。同时,3月底4月初华南已出现持续性降水雨带。所有这些特征都表明东亚大气环流可能在3月底4月初已经由冬季型开始转为夏季型。  相似文献   

太平洋,印度洋海温与夏季亚洲季风系统的联系     

黄琳  陆菊中 《气象科学》1990,10(2):182-191

本文采用相关普查法,对太平洋、印度洋海温变化与夏季亚洲季风系统(100hPa南亚高压、500hPa西北太平洋高压和南海高压)的遥相关分布特征作了详细分析和讨论。结果指出:前期(冬、春季)SST场的赤道东太平洋地区、黑潮区的海温变化对夏季季风系统的影响特别明显,且随着季节变化而不同。 同时,本文还分别通过北半球遥相关的水平结构,讨论了前期(冬、春季)SST影响夏季季风系统变化的可能途径。  相似文献   

影响南海夏季风爆发因子的诊断研究   总被引：10，自引：0，他引：10  

陈隽  金祖辉 《气候与环境研究》2001,6(1):19-32

通过南海夏季风爆发偏早年和偏晚年前期冬春季东亚地区的环流、积雪及海温等要素特征的诊断分析,揭示了南海夏季风爆发时间早晚与前期冬季东亚大气环流、热带对流、热源及热带太平洋海温的异常分布有密切联系,南海夏季风爆发偏早年的前期有冬季风偏强,高原积雪偏少,海洋大陆地区的对流活跃、热源增强及LaNina型海温分布等主要特征;南海夏季风爆发偏晚年的前期特征则基本相反。根据1997～1998年冬春环流、积雪及海温等的特征作了1998年南海夏季风爆发时间的预测,其结果与1998年的实况基本一致。  相似文献   

冬夏东亚季风环流对太平洋热状况的响应   总被引：9，自引：3，他引：6  

张庆云  王媛 《气候与环境研究》2006,11(4):487-498

冬夏隔季韵律关系一直是我国长期天气预报和短期气候预测的一个重要依据,然而迄今为止对它们之间的物理过程及成因机理并不十分清楚。利用NCEP/NCAR全球2.5°×2.5°网格月平均再分析资料,研究1951~2000年冬夏东亚季风环流异常变化与太平洋海面温度(SST)的关系及对关键海温区响应机理。研究指出:冬夏东亚季风环流隔季韵律关系及其年际变化与赤道东太平洋海面温度异常(SSTA)变化密切相关,冬季赤道东太平洋出现La Ni~na(El Ni~no)型的SST分布,有利冬、夏东亚季风环流加强(减弱),其影响过程通过赤道Walker环流强(弱)以及东亚地区Hadley环流强(弱)过程完成。冬季赤道东太平洋海温变化是冬、夏东亚环流季节以及年际变化的一个重要外强迫因子。  相似文献   

RELATIONSHIP BETWEEN THE SEASONAL TRANSITION OF EAST ASIAN MONSOON CIRCULATION AND ASIAN-PACIFIC THERMAL FIELD AND POSSIBLE MECHANISMS     

黄娇文  何金海  徐海明  金啟华 《热带气象学报(英文版)》2016,22(4):466-478

The NCEP/NCAR reanalysis, CMAP rainfall and Hadley Centre sea surface temperature (SST) datasets are used to investigate the relationship between the seasonal transition of East Asian monsoon and Asian-Pacific thermal contrast, together with the possible causes. Based on the 250 hPa air temperature over two selected key areas, the Asian-Pacific thermal difference (APTD) index is calculated. Results show that the APTD index is highly consistent with the Asian-Pacific Oscillation (APO) index defined by Zhao et al., in terms of different key areas in different seasons. Moreover, the time point of the seasonal transition of the Asian-Pacific thermal contrast can be well determined by the APTD index, indicative of seasonal variation in East Asian atmospheric circulation from winter to summer. The transition characteristic of the circulation can be summarized as follows. The continental cold high at lower tropospheric level moves eastward to the East China Sea and decreases rapidly in intensity, while the low-level northerlies turn to southerlies. At middle tropospheric level, the East Asia major trough is reduced and moves eastward. Furthermore, the subtropical high strengthens and appears near Philippines. The South Asia high shifts from the east of Philippines to the west of Indochina Peninsula, and the prevailing southerlies change into northerlies in upper troposphere. Meanwhile, both the westerly and easterly jets both jump to the north. The seasonal transition of atmospheric circulation is closely related to the thermal contrast, and the possible mechanism can be concluded as follows. Under the background of the APTD seasonal transition, the southerly wind appears firstly at lower troposphere, which triggers the ascending motion via changing vertical shear of meridional winds. The resultant latent heating accelerates the transition of heating pattern from winter to summer. The summer heating pattern can further promote the adjustment of circulation, which favors the formation and strengthening of the low-level southerly and upper-level northerly winds. As a result, the meridional circulation of the East Asian subtropical monsoon is established through a positive feedback between the circulation and thermal fields. Moreover, the time point of this seasonal transition has a significant positive correlation with the SST anomalies over the tropical central-eastern Pacific Ocean, providing a basis for the short-term climate prediction.  相似文献   

The Role of Land-sea Distribution and Orography in the Asian Monsoon. Part II： Orography     

XU Zhongfeng  QIAN Yongfu  FU Congbin 《大气科学进展》2010,27(3):528-542

The role of various mountains in the Asian monsoon system is investigated by AGCM simulations with different mountains. The comparison of the simulation with Asian mountains (MAsia run) with the simulation without mountains (NM run) reveals that the presence of the Asian mountains results in a stronger South Asian summer monsoon (SASM), characterized by enhanced lower-tropospheric westerly winds, upper-tropospheric easterly winds, and stronger water vapor convergence. In East Asia, the southerly winds and water vapor convergence are significantly strengthened in association with the intensified zonal pressure gradient between the East Asian continent and the Pacific Ocean. Both the dynamical and thermodynamic forcing of the Tibetan Plateau play important role in strengthening the Asian summer monsoon. In winter, the presence of Asian mountains significantly strengthens the continental high, which leads to a stronger Asian winter monsoon. The presence of African--Arabian mountains helps to intensify the exchange of mass between the Southern Hemisphere and Northern Hemisphere by strengthening the cross equatorial flows in the lower and upper troposphere over East Africa. Asian mountains also play a crucial role in the seasonal evolution of Asian monsoons. In comparison with the NM run, the earlier onset and later withdrawal of lower-tropospheric westerly winds can be found over South Asia in the MAsia run, indicating a longer SASM period. The African--Arabian mountains also moderately contribute to the seasonal variation of the South Asian monsoon. In East Asia, the clear south-to-north march of the southerly winds and subtropical rainfall starts to occur in early summer when the effects of Asian mountains are considered.  相似文献   

The interannual variability of East Asian Winter Monsoon and its relation to the summer monsoon   总被引：76，自引：1，他引：75  

Chen Wen  Hans-F. Graf  Huang Ronghui 《大气科学进展》2000,17(1):48-60

1.IntroductionOvertheEastAsiaregion,themostprominentsurfacefeatureofthewintermonsoonisstrongnortheasterliesalongtheeastflankoftheSiberianhighandthecoastofEastAsia.At500hPathereisabroadtroughcenteredaboutatthelongitudesofJapan.Thedominantfea-tureat2O0hPaistheEastAsianjetwithitsmaximumlocatedatjustsoutheastofJapan.Thisktisassociatedwithintensebaroclinicity,largeverticalwindshearandstrongadvectionofcoldair(StaffmembersofAcademiaSinica,l957,LauandChang,1987;BoyleandChen,1987;Chenetal.,1991…  相似文献   

Boreal summer continental monsoon rainfall and hydroclimate anomalies associated with the Asian-Pacific Oscillation   总被引：1，自引：0，他引：1  

Ping Zhao  Bin Wang  Xiuji Zhou 《Climate Dynamics》2012,39(5):1197-1207

With the twentieth century analysis data (1901–2002) for atmospheric circulation, precipitation, Palmer drought severity index, and sea surface temperature (SST), we show that the Asian-Pacific Oscillation (APO) during boreal summer is a major mode of the earth climate variation linking to global atmospheric circulation and hydroclimate anomalies, especially the Northern Hemisphere (NH) summer land monsoon. Associated with a positive APO phase are the warm troposphere over the Eurasian land and the relatively cool troposphere over the North Pacific, the North Atlantic, and the Indian Ocean. Such an amplified land–ocean thermal contrast between the Eurasian land and its adjacent oceans signifies a stronger than normal NH summer monsoon, with the strengthened southerly or southwesterly monsoon prevailing over tropical Africa, South Asia, and East Asia. A positive APO implies an enhanced summer monsoon rainfall over all major NH land monsoon regions: West Africa, South Asia, East Asia, and Mexico. Thus, APO is a sensible measure of the NH land monsoon rainfall intensity. Meanwhile, reduced precipitation appears over the arid and semiarid regions of northern Africa, the Middle East, and West Asia, manifesting the monsoon-desert coupling. On the other hand, surrounded by the cool troposphere over the North Pacific and North Atlantic, the extratropical North America has weakened low-level continental low and upper-level ridge, hence a deficient summer rainfall. Corresponding to a high APO index, the African and South Asian monsoon regions are wet and cool, the East Asian monsoon region is wet and hot, and the extratropical North America is dry and hot. Wet and dry climates correspond to wet and dry soil conditions, respectively. The APO is also associated with significant variations of SST in the entire Pacific and the extratropical North Atlantic during boreal summer, which resembles the Interdecadal Pacific Oscillation in SST. Of note is that the Pacific SST anomalies are not present throughout the year, rather, mainly occur in late spring, peak at late summer, and are nearly absent during boreal winter. The season-dependent APO–SST relationship and the origin of the APO remain elusive.  相似文献   

Variations of the summer Somali and Australia cross-equatorial flows and the implications for the Asian summer monsoon   总被引：3，自引：0，他引：3  

祝亚丽 《大气科学进展》2012,29(3):509-518

The temporal variations during 1948-2010 and vertical structures of the summer Somali and Australia cross-equatorial flows(CEFs) and the implications for the Asian summer monsoon were explored in this study.The strongest southerly and northerly CEFs exist at 925 hPa and 150 hPa level,respectively.The low-level Somali(LLS) CEFs were significantly connected with the rainfall in most regions of India(especially the monsoon regions),except in a small area in southwest India.In comparison to the climatology,the lowlevel Australia(LLA) CEFs exhibited stronger variations at interannual time scale and are more closely connected to the East Asian summer monsoon circulation than to the LLS CEFs.The East Asian summer monsoon circulation anomalies related to stronger LLA CEFs were associated with less water vapor content and less rainfall in the region between the middle Yellow River and Yangtze River and with more water vapor and more rainfall in southern China.The sea-surface temperature anomalies east of Australia related to summer LLA CEFs emerge in spring and persist into summer,with implications for the seasonal prediction of summer rainfall in East Asia.The connection between the LLA CEFs and East Asian summer monsoon rainfall may be partly due to its linkage with El Nino-Southern Oscillation.In addition,both the LLA and LLS CEFs exhibited interdecadal shifts in the late 1970s and the late 1990s,consistent with the phase shifts of Pacific Decadal Oscillation(PDO).  相似文献   

East Asian summer monsoon circulation structure controlled by feedback of condensational heating   总被引：1，自引：0，他引：1  

Qiong Jin  Xiu-Qun Yang  Xu-Guang Sun  Jia-Bei Fang 《Climate Dynamics》2013,41(7-8):1885-1897

The East Asian summer monsoon (EASM) features strong humid low-level southerly flows and abundant rainfall over the subtropical East Asia. This study identified how condensational heating generated by the EASM rainfall can affect the EASM circulation by contrasting two 10-member ensembles of atmospheric General Circulation Model experiments with Community Climate Model version 3/National Center for Atmospheric Research respectively with and without feedback of condensational heating over the East Asian domain. Major results inferred from the experiments are as follows. Condensational heating is found to absolutely dominate diabatic heating over East Asia. Exclusion of the feedback of condensational heating leads to a significant weakening of summertime tropospheric warming over land and thus a large reduction of the land-sea thermal contrast between entire Asian continent and surrounding oceans. Associated with this, the lower-level EASM flows are weakened, South Asian High at 200 hPa migrates southward with reduced intensity and breaks over East Asia with southerly flows prevailing in the upper troposphere, in contrast to northerly flows in reality. Consequently, local EASM meridional cell disappears and the baroclinic structure featured by the EASM circulation that is dynamically determined by convective condensational heating over East Asia is altered to a barotropic structure. Therefore, it is concluded that the feedback of condensational heating acts to largely enhance lower-level flows of the EASM and essentially determine its baroclinic structure and meridional cell, once the solar radiation and inhomogeneity of the Earth’s surface form low-level monsoon flows in East Asia by enhancing land-sea thermal contrast.  相似文献   

青藏高原西侧绕流风系的变化及其与东亚夏季风和我国华北地区夏季降水的关系   总被引：17，自引：4，他引：13  

黄刚  周连童 《气候与环境研究》2004,9(2):316-330

从观测资料分析了青藏高原西侧绕流偏北风系的年际和年代际变化及其与东亚夏季风和华北地区夏季降水的关系。研究表明 ,前者对后者有很大影响 ,若夏季青藏高原西侧绕流的偏北风系强 ,则东亚夏季风偏南风分量强 ,且华北地区夏季降水可能偏多 ;相反 ,若夏季青藏高原西侧绕流的偏北风系弱 ,则东亚夏季风的偏南风分量弱 ,且华北地区夏季降水可能偏少。分析结果还表明 ,由于从 1 965年之后 (特别从 1 977年之后 ) ,高原西侧绕流的偏北风系减弱 ,可能导致了东亚夏季风的偏南风分量减弱 ,使得输向华北的水汽大大减弱 ,且引起华北地区降水减少 ,发生了持续严重干旱。  相似文献   

Weakening of Indian summer monsoon in recent decades   总被引：13，自引：3，他引：10  

WU Bingyi 《大气科学进展》2005,22(1):21-29

The analysis of 43 years of NCEP-NCAR reanalysis data and station observations reveals the connections between tropospheric temperature variations and the weakening of the Indian summer monsoon circulation. The Indian summer monsoon variation is strongly linked to tropospheric temperature over East Asia, showing significant positive correlations of mean tropospheric temperature with all-Indian summer rainfall and the monsoon circulation intensity. The result shows that Indian summer monsoon circulation underwent two weakening processes in recent decades. The first occurred in circa the mid-1960s, and the other occurred in circa the late 1970s. The finding indicates that the mean tropospheric temperature may play a crucial role in the weakening of the Indian summer monsoon intensity via changing land-sea thermal contrast. The role of the tropospheric temperature contrast between East Asia and the tropical area from the eastern Indian Ocean to the tropical western Pacific is to weaken the Indian summer monsoon circulation.  相似文献   

云南夏季旱涝与前期冬季环流变化的关系   总被引：3，自引：0，他引：3       下载免费PDF全文

晏红明 王灵周国连  鲁亚斌 《应用气象学报》2007,18(3):340-349

夏季气候异常的前期信号特征分析一直是短期气候预测工作的重点。利用1948—2004年NCEP/NCAR月平均再分析资料、1961—2004年云南124个站的月平均降水和1948—2003年英国Hadley中心的月平均海温资料, 分析了云南夏季旱涝的时空特征, 探讨了云南夏季旱涝与前期大气环流和大气热力状态变化的关系, 发现云南夏季旱涝前冬12月—1月, 特别是1月东亚中高纬度地区的大气环流变化和赤道附近高低层大气的热力状态对云南夏季旱涝有重要的指示意义, 当前冬东亚大槽强 (弱), 冬季风强 (弱), 赤道附近高低层大气温度偏低 (高) 时, 后期云南夏季降水偏多 (少)。同时, 初步探讨了东亚冬夏季风环流变化的相互联系及热带海温变化的可能影响, 指出冬季到夏季印度洋和赤道西太平洋地区持续的海温异常有可能通过改变夏季海陆的热力对比, 进而影响夏季风活动和云南夏季降水的变化。  相似文献