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1.
利用NCEP/NCAR发布的850 hPa风场和OLR场以及福建38个站月降水资料, 分析了福建夏季旱涝与东亚夏季风及西太平洋副高的关系。结果表明夏季旱涝与夏季风强弱及副高南北位置密切相关。涝 (旱) 年在东亚季风系统中的热带季风环流出现异常加强 (减弱), 副热带季风环流则出现异常减弱 (加强); 涝年副高平均脊线位置偏北于27°N附近, 旱年则偏南于24°N附近; 由春入夏, 再由夏入秋副高南北位置的季节位移, 涝年先是急速北跳, 而后又急速南撤, 旱年却进退平缓。旱涝年东亚中高纬度环流亦表现出不同特征, 涝 (旱) 年一般没有 (有) 出现阻塞形势, 中纬度纬 (经) 向环流发展, 副热带锋区北抬 (南压), 研究还进一步揭示了夏季副高位置南北偏离影响夏季各月降水及其分布的不同形式。 相似文献
2.
利用欧洲中心1980~1989年逐日200hPa、850hPa风场及日本气象研究所提供的GMS观测的TBB逐日资料,探讨了夏季东亚热带、副热带季风的强弱对中国东部夏季降水的影响.指出东亚夏季风系统中的两条辐合带热带辐合带(热带季风槽)和副热带辐合带(副热带梅雨锋)的强度的变化呈相反趋势,即热带季风槽偏弱时(弱季风),副热带梅雨锋偏强;反之热带季风槽偏强时(强季风),副热带梅雨锋偏弱.江淮流域的降水与热带季风槽、副热带梅雨锋的强度密切相关,即热带季风槽偏弱(弱季风),梅雨锋偏强时,江淮流域的降水偏多;热带季风槽偏强(强季风),梅雨锋偏弱时,江淮流域的降水偏少.研究表明:热带季风槽和副热带梅雨锋的强度与偏西气流的加强密切相关.当赤道东太平洋海温偏高,赤道西太平洋海温偏低,黑潮地区的海温偏高时,赤道东西太平洋上空的Walker环流和西太平洋中纬度Hadley环流的下沉支气流减弱,东亚季风槽较弱(弱季风),梅雨锋较强;当赤道东太平洋海温偏低、西太平洋海温偏高,黑潮地区的海温偏低时,赤道东西太平洋上空的Walker环流和西太平洋中纬度Hadley环流的下沉支气流加强,东亚季风槽较强(强季风),梅雨锋较弱. 相似文献
3.
利用NCAR/NCEP月平均再分析资料,探讨夏季西太平洋副热带高压异常时东亚热带季风、梅雨锋及中高纬环流的变化特征.研究表明:夏季西太平洋副热带高压脊线异常偏南或脊点异常偏西时,东亚夏季风环流偏弱,850 hPa矢量风距平场上东亚热带地区出现反气旋性环流,副热带地区呈气旋性环流,500 hPa垂直速度距平场上东亚热带地区上升运动减弱,梅雨锋区上升运动加强,500 hPa高度上东亚高纬鄂霍次克海区域出现阻塞高压,高纬冷空气直达中纬度,梅雨锋扰动加强,造成江淮流域汛期降水偏多.夏季西太平洋副热带高压脊线异常偏北或脊点异常偏东时,东亚夏季风环流偏强,东亚大气环流系统的活动出现了与上述情况相反的异常型,江淮流域汛期降水偏少. 相似文献
4.
利用1979—2013年夏季全球2.5°×2.5°逐日环流资料和中国气象站点降水观测资料,采用动力学因子(西南风)与热力学因子(Radiation Longwave covting, OLR)相结合定义了标准化的亚洲热带夏季风指数(Tropical Summer Monsoon Index, TSMI)。结果表明,该指数能够很好地描述亚洲热带夏季风的年际变化和准4 a变化特征,并能够指示中国南方夏季降水的异常变化和东亚大气环流特征。强(弱)亚洲热带夏季风年,印度夏季风槽和南海夏季风槽加强加深(减弱),孟加拉湾海域一致西南风(东风)异常,越赤道急流向北输送偏强(偏弱),南海季风槽位置偏西(东),南海区域一致西南风异常,西太平洋副热带高压和南亚高压纬向位置分离(重叠),低层气流在长江流域辐散(辐合),华南地区辐合(辐散),长江中下游流域出现异常下沉(上升)运动,造成长江流域降水偏少(偏多),华南地区降水比常年偏多(偏少)。 相似文献
5.
东亚副热带季风特征及其指数的建立 总被引:18,自引:2,他引:16
基于大气对流活动和非绝热加热的分析,给出东亚夏季风区域变化特征,客观地确定东亚副热带季风及热带季风对流强度,并由此建立其与大尺度季风环流的内在联系,提出分别用所对应区域经向风垂直切变来构造季风指数.对比分析显示,上述季风指数在反映夏季环流和降水等方面效果显著,能很好地刻划东亚夏季风强度.同时指出,东亚副热带季风指数与西太平洋副热带高压及长江中下游降水密切相关,在空间场上表现出东亚/太平洋型(EAP型)遥相关特征.高指数年副高偏南,长江中下游为涝;低指数年则相反. 相似文献
6.
利用NCEP/NCAR再分析资料、CMAP降水及Hadley环流中心海温资料等,对东亚季风环流由夏向冬的季节转变与中国前冬气候的关系进行了研究。参考前人定义的亚太热力差指数,计算了1979-2016年亚太热力场由夏向冬的季节转变时间(平均为56. 6候)。结果表明,该季节转变时间点能很好地表征东亚季风环流由夏向冬的季节转变。东亚季风环流由夏向冬的转变特征表现为:低层大陆热低压转为大陆冷高压,阿留申低压形成加强,低空偏南风转为偏北风;中层东亚大槽形成,副高单体减弱成一个副热带高压带;高层南亚高压中心从青藏高原移至菲律宾以东洋面上,高空偏北风转为偏南风。此外由夏向冬的季节转变时间与中国前冬降水和地面气温有着紧密的联系,并且该转变时间的早晚与前期夏季热带太平洋的海温呈现类ENSO异常海温型的相关分布,即表现为前期夏季热带中东太平洋海温偏低(高)时,后期东亚夏季型季风环流向冬季型季风环流转变易偏晚(早),这对东亚季风环流季节转变的预测提供了依据。 相似文献
7.
梅雨期及其前后东亚地区的经向环流结构 总被引:1,自引:1,他引:1
本文分析了1983年江淮流域入梅前、梅雨期以及出梅后东亚地区各期平均的经向环流结构及其演变特征。在不同时期,印度热带季风环流和东亚热带及副热带季风环流具有显著差异。研究指出,江淮流域梅雨是亚洲夏季三个季风系统相互作用的结果,是东亚副热带季风系统中经向环流上升支中的产物,同时又与其它两个季风系统密切相关,梅雨结束则与印度热带季风环流减弱南撤、西太平洋高压加强西伸、东亚副热带季风环流北上有关。 相似文献
8.
梅雨期及其前后东亚地区的径向环流结构 总被引:2,自引:0,他引:2
本文分析了1983年江淮流域入梅前、梅雨期以及出梅后东亚地区各期平均的径向环流结构及其演变特征。在不同时期,印度热带季风环流和东亚热带及副热带季风环流具有显著差异。研究指出,江淮流域梅雨是亚洲夏季三个季风系统相互作用的结果,是东亚副热带季风系统中径向经向环流上升支中的产物,同时又与其它两个季风系统密切相关,梅雨结束则与印度热带季风环流减弱南撤、西太平洋高压加强西伸、东亚副热带季风环流北上有关。 相似文献
9.
东亚冬季风指数及其对东亚大气环流异常的表征 总被引:26,自引:2,他引:26
基于月平均NCEP/NCAR再分析资料、CMAP全球降水资料及中国台站降水和冷空气资料,首先概括了东亚冬季风环流系统的主要成员,并对基于这些环流系统定义的有代表性的4种东亚冬季风指数进行了比较分析。结果表明,4种指数具有比较一致的年际和年代际变化特征,相互间都为显著正相关,表明各指数都能较好地反映出其他环流系统成员的异常。功率谱分析结果显示,所有东亚冬季风指数均具有3—4年的年际变化周期和6.5年周期及9—15年的年代际变化周期。此外绝大部分指数在20世纪80年代之后都有线性减弱的趋势。所有季风指数都能够很好地反映“强(弱)冬季风年,低层西伯利亚高压偏强(弱),阿留申低压偏深(浅),副热带北风气流偏强(弱),东亚副热带地区气温偏低(高),中层东亚大槽偏深(浅)及高层副热带西风急流偏强(弱)”的基本特性。但各指数与冬季影响中国的冷空气次数间均无很好的对应关系。另外,绝大多数指数与东亚地区夏季降水也有较好的滞后关系,表明冬季风不仅对同期环流系统存在作用,而且还可能影响到夏季。 相似文献
10.
本文基于华北夏季降水数据、NCEP/NCAR再分析环流数据,采用了相关、合成和环流异常回归重构等方法,分析了东亚副热带夏季风指数、华北大气动力上升指数与华北夏季降水的关系。主要结果如下:1)东亚副热带夏季风指数、华北大气动力上升指数与华北夏季降水有很好的对应关系。当两个指数偏强时,华北夏季降水会异常偏多;两个指数偏弱,华北夏季降水异常偏少;如果两个指数强弱不一致时,华北会出现区域性降水偏多情况,但全区整体降水量基本为正常值。2)华北夏季降水异常是东亚副热带夏季风和华北大气动力上升运动协同作用的结果。在东亚副热带夏季风指数、华北大气动力上升指数偏强年,夏季500 hPa层贝加尔湖槽会加深、西北太平洋副热带高压会偏北,华北处于“东高西低”的环流型控制下,西部低槽东移受阻,在华北维持较长时间的大气上升运动;850 hPa层印度夏季风、东亚副热带夏季风会偏强,这时热带印度洋西风水汽输送以及东亚副热带地区偏南风水汽输送或东南风水汽输送会加强,华北水汽来源充足。这种高、低空环流配置非常有利于造成华北夏季降水异常偏多。反之,华北夏季降水会异常偏少。3)前期4—5月,东亚副热带夏季风指数、华北大气动力上升指数偏强,可以作为华北夏季降水异常偏多的一个气候监测预测指标。 相似文献
11.
Correlation analysis identified that Indian summer rainfall and East Asian 500 hPa geopotential height field are significantly correlated.A teleconnection pattern between Indian monsoon and East Asian summer circulation (IEA pattern) was proposed.We suggested that the Pacific-Japan teleconnection pattern (PJ pattern) primarily influences the meridional position of the northwestern Pacific subtropical high (NPSH) in summer,while IEA pattern partly affects its zonal stretch or the anomaly of geopotential height field over China mainland.The numerical experiments imply that the IEA pattern has important impact on East Asian circulation and it can be stimulated by the SST anomaly of the Indian Ocean.We summarized that there are two ways,a directive way and a selective way,by which ENSO exerts impacts on East Asian summer monsoon. 相似文献
12.
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
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
13.
利用NCEP/NCAR再分析资料、Hadley中心海温资料及CMAP降水资料等,通过亚澳季风联合指数挑选异常年份,对东亚夏季风和澳洲冬季风强度反相变化特征进行研究。结果表明,当东亚夏季风偏强、澳洲冬季风偏弱时,南北半球中低纬地区都出现了复杂的异常环流系统。在热带地区对流层低层,西北太平洋为异常反气旋式环流系统所控制,与南太平洋赤道辐合带的异常反气旋环流在赤道地区发生耦合,形成赤道异常东风,而在南北印度洋上则存在两个异常气旋式环流系统。在这两对异常环流之间的海洋性大陆地区,出现赤道以南为反气旋环流而赤道以北为气旋式环流。在东亚季风区,东南沿海的东侧海洋上存在反气旋异常,中国东南地区受异常反气旋西南侧的东南风影响。此外,澳洲北部受异常西风影响。这就形成了东亚夏季风偏强、澳洲冬季风偏弱的情形,从而东亚夏季风和澳洲冬季风活动出现了强弱互补的变化特征。当东亚夏季风偏弱、澳洲冬季风偏强时,南北半球的环流特征则出现与上述相反的环流特征。总体而言,当东亚夏季风偏强、澳洲冬季风偏弱时,东亚—澳洲季风区在南北半球呈现出不同的气候异常分布特征,即北半球降水北少南多、气温北高南低,南半球降水西多东少、气温西高东低。 相似文献
14.
Bhaskar Preethi Milind Mujumdar Amita Prabhu Ramesh Kripalani 《Asia-Pacific Journal of Atmospheric Sciences》2017,53(2):305-325
Coupled Model Inter-comparison Project Phase 5 (CMIP5) model outputs of the South and East Asian summer monsoon variability and their tele-connections are investigated using historical simulations (1861-2005) and future projections under the RCP4.5 scenario (2006-2100). Detailed analyses are performed using nine models having better representation of the recent monsoon teleconnections for the interactive Asian monsoon sub-systems. However, these models underestimate rainfall mainly over South Asia and Korea-Japan sector, the regions of heavy rainfall, along with a bias in location of rainfall maxima. Indeed, the simulation biases, underestimations of monsoon variability and teleconnections suggest further improvements for better representation of Asian monsoon in the climate models. Interestingly, the performance of Australian Community Climate and Earth System Simulator version 1.0 (ACCESS1.0) in simulating the annual cycle, spatial pattern of rainfall and multi-decadal variations of summer monsoon rainfall over South and East Asia appears to more realistic. In spite of large spread among the CMIP5 models, historical simulations as well as future projections of summer monsoon rainfall indicate multi-decadal variability. These rainfall variations, displaying certain epochs of more rainfall over South Asia than over East Asia and vice versa, suggest an oscillatory behaviour. Teleconnections between South and East Asian monsoon rainfall also exhibit a multi-decadal variation with alternate epochs of strengthening and weakening relationship. Furthermore, large-scale circulation features such as South Asian monsoon trough and north Pacific subtropical high depict zonal oscillatory behaviour with east-west-east shifts. Periods with eastward or westward extension of the Mascarene High, intensification and expansion of the upper tropospheric South Asian High are also projected by the CMIP5 models. 相似文献
15.
Weakening of Indian summer monsoon in recent decades 总被引:13,自引:3,他引:10
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
16.
The East Asian summer monsoon: an overview 总被引:38,自引:1,他引:38
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. 相似文献
17.
Lu Peisheng 《大气科学进展》1995,12(3):311-318
卢佩生EvolutionofAsianSummerMonsoonandtheSlowlyVaryingDisturbances¥LuPeisheng(InstituteofAtmosphericPhysics,ChineseAcademyofScie... 相似文献
18.
The IAP 2-L AGCM is modified by introducing a set of climatological surface albedo data into the model for substituting the model’s original surface albedo parameterization. The comparison between the observations and the simulation results by the modified model shows that the general features of the East Asian summer monsoon can be well reproduced by the modified IAP 2-L AGCM. Especially for the simulation of monsoon precipitation, the modi-fied model can well reproduce not only the monthly mean features of the summer monsoon rainfall over East Asia, but also the stepwise advance and retreat of the East Asian summer monsoon rainbelt. Analysis results demonstrate that the good simulation of the monsoon rainfall is closely related to the reasonable simulation of the large scale gen-eral circulation over East Asian region, such as the western Pacific subtropical high, Asian monsoon low and the low level flows. The good performance of the modified model in the rainfall simulation shows its great potential to serve as a useful tool for the prediction of summer drought / flood events over East Asia. 相似文献
19.
东亚夏季风降水和环流数值模拟对不同对流参数化方案的敏感性 总被引:4,自引:2,他引:4
A 5-level spectral AGCM (ImPKU-5LAGCM) is used to examine the sensitivity of the simulated results of the summer monsoon rainfall and circulation in East Asia to different cumulus parameterization schemes in the climatological-mean case and in the cases of weak and strong Asian summer monsoons,respectively. The results simulated with the Arakawa-Schubert's(hereafter A-S's), Kuo's and Manabe's cumulus parameterization schemes show that these simulated distributions of the summer monsoon rainfall and circulation in East Asia depend strongly on the cumulus parameterization schemes either in the climatological-mean case or in the cases of weak and strong Asian summer monsoons. From the simulated results, it might be shown that the Kuo scheme appears to be more suitable for the simulation of the summer monsoon rainfall and circulation in East Asia than the A-S scheme or the Manabe scheme, although the A-S scheme is somewhat better in the simulations of the tropical rainfall. This might be due to that the Kuo's cumulus parameterization scheme is able to reflect well the characteristics of rainfall cloud system in the East Asian summer monsoon region, where the rainfall system used to be a mixing of cumulus and stratus. 相似文献
20.
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. 相似文献