2012年冬春季高原积雪异常对亚洲夏季风的影响   总被引：2，自引：1，他引：1  

竺夏英  陈丽娟  李想 《气象》2013,39(9):1111-1118

利用罗格斯大学积雪遥感资料、NCEP/NCAR再分析格点资料和NOAA陆地降水分析数据PREC/L,从2011/2012年冬春季青藏高原积雪偏多现象与亚洲夏季风的观测事实与以往研究结果不一致出发,诊断分析了2011/2012年冬春积雪与亚洲夏季风的可能联系。结果表明：2012年春季和前期冬季,青藏高原主体上空对流层主要为气旋性环流距平且气温偏低,这与积雪偏多年的环流特征一致。尤其在90°E以西,自青藏高原到热带地区,前期冬春季对流层中部气温表现为北冷南暖的距平特征,有利于夏季自热带印度洋到高原温度梯度偏弱,造成南亚夏季风偏弱。但是在90°E以东的高原东部到东亚地区及其南侧的低纬度地区,对流层温度距平为北正南负型,温度梯度偏弱,有利于亚洲东南部大气环流冬夏季节转换偏早,南海夏季风爆发偏早,东亚夏季风偏强,这种环流特征受到高原以外的其他外强迫信息的影响。2011/2012年冬春季积雪偏多特征可能对南亚夏季风偏弱有重要贡献,而对东亚夏季风的影响不明显。  相似文献   

青藏高原热源异常对1999年东亚夏季风异常活动的影响   总被引：13，自引：4，他引：9  

孙颖  丁一汇 《大气科学》2002,26(6):817-828

以1999年青藏高原的热源异常为出发点,讨论了其对东亚夏季风异常活动的影响,并从陆气相互作用的角度分析了该年热源异常的原因.结果表明,1999年青藏高原大气热源建立的时间明显偏晚,春夏季热源强度异常偏弱.这使得向高原的低层流入气流明显偏弱,垂直上升运动减弱,向高原的辐合减少,季风经圈环流变弱,高原南侧、东南侧的西南夏季风减弱,引起了夏季风的爆发偏晚及在中国东部北进的偏弱.而进一步对热源异常成因的分析表明,陆面因子的异常变化所引起的感热加热偏弱是热源偏弱的主要因子.高原积雪的减幅在春夏季变小,地表温度的增加变慢,地表温度偏低,引起了感热加热在春夏季的偏弱,进而导致了热源异常.  相似文献   

春季青藏高原表面感热加热的年际变化特征及其对印度夏季风爆发时间的影响   总被引：1，自引：0，他引：1  

张盈盈  李忠贤  刘伯奇 《大气科学》2015,39(6):1059-1072

本文基于日本气象厅(JMA)的JRA-25再分析资料,分析了春季青藏高原表面感热加热年际变化的时空特征,及其对印度夏季风爆发过程的影响。EOF分析结果表明,春季高原感热加热的年际变化在高原中西部最为明显,这主要与局地地-气温差的年际变率有关。统计分析表明,当春季高原中西部表面感热偏强(弱)时,印度夏季风爆发偏早(晚),且高原中西部表面感热与ENSO事件无显著相关。春季高原中西部感热能够通过改变印度季风区对流层高层和低层的经向热力结构来影响印度夏季风的爆发时间。当春季高原中西部感热偏强时,造成的上升气流在高原以西的印度季风区北部下沉,通过绝热增暖引起局地对流层中上部的异常暖中心,令印度季风区对流层中上部平均温度经向梯度由冬至夏的季节性反转提早。同时,印度季风区北部的下沉运动能够抑制当地降水,令陆面温度升高,并通过非绝热过程造成对流层低层的异常暖中心,进一步增强了印度季风区的海陆热力对比。在印度季风区以北地区对流层高、低层异常增暖的共同作用下,印度夏季风提前爆发。  相似文献   

地表反照率与高原夏季风爆发关系分析     

曹晓云  陈爱军  肖建设  卞林根  郑照军 《气候与环境研究》2019,24(6):785-794

利用2000～2016年MODIS地表反照率和ECMWF/ERA-Interim再分析资料,选取有代表性的高原季风指数DPMI,统计分析了青藏高原地表反照率与高原季风之间的联系,结果表明:1)11月高原地表反照率大小与次年高原夏季风爆发存在密切关系:11月高原地表反照率偏低(高),次年4月高原夏季风爆发偏早(晚),强度偏强(弱)。2)可能的影响机制为:当前期11月高原地表反照率偏低时,后期高原主体对大气的感热加热信号更强,从而引起4月高原上空近地面层上升运动明显加强,这有利于热量向高空传输,导致对流层加热作用加强,高原上空对流层温度偏高,使得高原季风环流系统加强,最终导致高原季风季节变化相应提前;反之亦然。  相似文献   

青藏高原冬季积雪影响我国夏季降水的模拟研究   总被引：23，自引：9，他引：14  

朱玉祥  丁一汇  刘海文 《大气科学》2009,33(5):903-915

利用区域气候模式 (NCC_RegCM1.0) 对青藏高原前冬积雪对次年夏季中国降水的影响进行了数值模拟研究, 所得结果与实际观测的积雪和降水的关系较为吻合, 即长江流域、 新疆地区夏季多雨, 华北和华南少雨, 这与我国最近二十年来维持的 “南涝北旱” 雨型较为一致。因此, 可以认为青藏高原冬季多雪, 是引起中国东部夏季降水出现 “南涝北旱” 的一个重要原因。本文揭示了青藏高原冬季积雪影响我国夏季降水的可能物理机制。青藏高原冬季多雪, 会导致青藏高原地面感热热源减弱, 这种热源的减弱在冬季导致冬季风偏强, 可以影响到我国华南、 西南及孟加拉湾地区。同时, 由于高原热源的减弱可持续到夏季, 成为东亚夏季风和南亚夏季风减弱的一个原因。在积雪初期, 地面反射通量的增加起了主要作用; 在积雪融化后, “湿土壤” 在延长高原积雪对天气气候的影响过程中起了重要作用。初期的反射通量增加减少了太阳辐射的吸收、 融雪时的融化吸热, 以及后期的湿土壤与大气的长期相互作用, 作为异常冷源, 减弱了春夏季高原热源, 是高原冬季积雪影响夏季风并进而影响我国夏季降水的主要机理。本文的模拟结果表明, 青藏高原冬季积雪的显著影响时效可以一直持续到6月份。  相似文献   

青藏高原和热带印度洋5月热力异常与新疆夏季降水的关系     

王天竺  赵勇 《高原气象》2021,40(1):1-14

基于1979-2017年美国国家海洋和大气管理局(NOAA)提供的海表温度资料和美国国家环境预测中心(NCEP)/美国国家大气研究中心(NCAR)提供的大气环流再分析资料以及青藏高原地区149个站点观测资料计算的地表感热通量和新疆气象信息中心提供的全疆81站逐月降水资料等,研究了5月青藏高原和热带印度洋加热对新疆夏季降水的单独影响和共同影响。结果表明:5月高原感热和印度洋海表温度的异常呈较好的持续性,异常可持续至夏季。奇异值分解(SVD)分析发现5月高原东部(90°E为界)感热与新疆北部及塔里木盆地西南部夏季降水呈显著负相关,热带印度洋海温与塔里木盆地西部夏季降水呈显著正相关。当仅考虑高原感热影响时,高原东部感热偏强(弱)时,对应北疆夏季降水将偏少(多);当仅考虑热带印度洋海温影响时,海温偏暖(冷)时,塔里木盆地西部地区夏季降水偏多(少)。当高原感热和热带印度洋海温均偏强(弱)时,北疆夏季降水将偏少(多),南疆夏季降水将偏多(少)。当高原感热偏强(弱),热带印度洋海温偏弱(强)时,中亚副热带西风急流位置偏北(偏南),中亚和贝加尔湖地区上空分别为异常反气旋(异常气旋)和异常气旋(异常反气旋)控制,新疆上空盛行偏北(南)风,同时热带印度洋水汽不能(能)输送至新疆上空导致新疆夏季降水偏少(多)。  相似文献   

青藏高原地面热源对亚洲季风爆发的热力影响   总被引：23，自引：4，他引：23  

张艳  钱永甫 《南京气象学院学报》2002,25(3):298-306

利用多年NCEP/NCAR再分析全球逐候平均气象场资料和逐旬感热、潜热资料，对亚洲夏季风爆发期间青藏高原及其邻近地区地面加热场的特征进行分析。着重讨论了高原和邻近地区感热加热对亚洲夏季风爆发的影响，具体分析了高原感热加热对亚洲夏季风推进的影响机制，以及对热带低层西风气流的作用。结果发现，中纬度主原的感热加热所造成的经、纬向热力差异是导致亚洲夏季风爆发的原因。亚洲夏季风建立区域和时间的差异与高原感热加热的区域性有关。高原感热加热在南海夏季风爆发前后对南海地区低层西风所流所起的作用不同，在季风爆发前是加速低层西风，在季风爆发后起削弱西风气流的作用。对亚洲夏季风爆发早年和晚年的感热加热进行了对比分析，发现亚洲夏季风爆发时间的年际变化与热源的年际变化有关。  相似文献   

青藏高原地面-对流层系统的能量收支   总被引：3，自引：3，他引：3  

沈志宝  成天涛  王可丽 《高原气象》2002,21(6):546-551

利用CCM3中的辐射模式CRM，计算了1月和7月地－气系统、地面－对流层系统和地面辐射能收支，研究了青藏高原地面－对流层系统辐射能收支的冬、夏季节特征及其与地面和地－气系统辐射能收支的关系，并与东部平原地区和高原北侧干旱地区比较。文中还讨论了云和高原冬季地面积雪对辐射能收支的影响，比较了大气辐射加热和地面感热通量对夏季高原对流层大气加热的贡献。  相似文献   

亚洲夏季风的爆发和年际变化同海─陆热力对比的关系     

闵文彬  MichioYanai 《四川气象》1997,(3)

我们用1979年至1992年共14年的资料，研究亚洲夏季风的爆发和年际变化同海-陆热力对比的关系及其贡献因子．亚利夏季风和西藏高原南部对流层上部经向温度梯度的逆转是同时发生的，这种梯度的速转是由于5—6月中心位于高原的欧亚地区温度大幅度增加，而印度洋温度没有明显变化过成的．西藏高原春天是一个热源，此热源明显与同赤道印度洋雨带相关的热源分开，它主要归因于地表感热通量的贡献，而海洋热源则归国于凝结潜热的开放．不管凝结加热有多强，印度洋的凝结加热没能使对流层变暖，这是因为凝结加热与上升空气的绝热冷却相抵消；春季高原地区的感效输送才是导致经向温度梯度逆转的主要原因．根据北印度洋纬向风的夏季平均垂直切变量而确定的季风强度指数，被用来比较亚洲夏季风环流的强、弱年．亚洲夏季风的强（弱）与下面几点有关：（a）欧亚对流层温度为正（负）距平，而印度洋和东太平洋为负（正）温度距平；（b）赤道道太平洋、阿拉伯海、孟加拉湾和南海为负（正）海面温度（SST）距平，（c）亚洲季风区和西太平洋为强（弱）加热区和积云对流区，而赤道太平洋为弱（强）加热区和积云对流区．  相似文献   

2006年高原夏季风强弱变化及其与西南地区东部夏季气温和降水的关系     

《干旱气象》2015,(4)

利用2006年西南地区东部37个测站逐日降水量、气温资料和NCEP/NCAR R2再分析日平均资料,通过相关分析和合成分析,研究分析了高原夏季风季节内变化特征,讨论了高原夏季风强弱变化特征及其与西南地区东部夏季气候的关系。结果表明:高原夏季风的变化和西南地区东部夏季气候变化关系密切。当高原夏季风偏强(弱)时,南亚高压、中高纬度环流、西太副高、西风带环流、低层流场以及垂直运动等均有显著变化,进而影响到西南地区东部夏季气候。高原夏季风的季节内变化与青藏高原大气热源呈显著正相关关系,青藏高原热力作用对高原夏季风的异常变化有重要作用。  相似文献   

Land–sea heating contrast in an idealized Asian summer monsoon     

C.?ChouEmail author 《Climate Dynamics》2003,21(1):11-25

Mechanisms determining the tropospheric temperature gradient that is related to the intensity of the Asian summer monsoon are examined in an intermediate atmospheric model coupled with a mixed-layer ocean and a simple land surface model with an idealized Afro–Eurasian continent and no physical topography. These include processes involving in the influence of the Eurasian continent, thermal effects of the Tibetan Plateau and effects of sea surface temperature. The mechanical effect on the large-scale flow induced by the Plateau is not included in this study. The idealized land–sea geometry without topography induces a positive meridional tropospheric temperature gradient thus a weak Asian summer monsoon circulation. Higher prescribed heating and weaker surface albedo over Eurasia and the Tibetan Plateau, which mimic effects of different land surface processes and the thermal effect of the uplift of the Tibetan Plateau, strengthens the meridional temperature gradient, and so as cold tropical SST anomalies. The strengthened meridional temperature gradient enhances the Asian summer monsoon circulation and favors the strong convection. The corresponding monsoon rainbelt extends northward and northeastward and creates variations of the monsoon rainfall anomalies in different subregions. The surface albedo over the Tibetan Plateau has a relatively weak inverse relation with the intensity of the Asian summer monsoon. The longitudinal gradient of ENSO-like SST anomalies induces a more complicated pattern of the tropospheric temperature anomalies. First, the positive (negative) longitudinal gradient induced by the El Niño (La Niña)-like SST anomalies weakens (strengthens) the Walker circulation and the circulation between South Asia and northern Africa and therefore the intensity of the Asian summer monsoon, while the corresponding monsoon rainbelt extends northward (southward). The El Niño (La Niña)-like SST anomalies also induces colder (warmer) tropospheric temperature over Eurasia and warmer (colder) tropospheric temperature over the Indian Ocean. The associated negative (positive) meridional gradient of the tropospheric temperature anomalies is consistent with the existence of the weak (strong) Asian summer monsoon.  相似文献   

A Modeling Study of the Effects of Anomalous Snow Cover over the Tibetan Plateau upon the South Asian Summer Monsoon   总被引：1，自引：0，他引：1  

刘华强  孙照渤王举 闵锦忠 《大气科学进展》2004,21(6):964-975

The effect of anomalous snow cover over the Tibetan Plateau upon the South Asian summer monsoon is investigated by numerical simulations using the NCAR regional climate model (RegCM2) into which gravity wave drag has been introduced. The simulations adopt relatively realistic snow mass forcings based on Scanning Multi-channel Microwave Radiometer (SNINIR) pentad snow depth data. The physical mechanism and spatial structure of the sensitivity of the South Asian early summer monsoon to snow cover anomaly over the Tibetan Plateau are revealed. The main results are summarized as follows. The heavier than normal snow cover over the Plateau can obviously reduce the shortwave radiation absorbed by surface through the albedo effect, which is compensated by weaker upward sensible heat flux associated with colder surface temperature, whereas the effects of snow melting and evaporation are relatively smaller.The anomalies of surface heat fluxes can last until June and become unobvious in July. The decrease of the Plateau surface temperature caused by heavier snow cover reaches its maximum value from late April to early May. The atmospheric cooling in the mid-upper troposphere over the Plateau and its surrounding areas is most obvious in May and can keep a fairly strong intensity in June. In contrast, there is warming to the south of the Plateau in the mid-lower troposphere from April to June with a maximum value in May.The heavier snow cover over the Plateau can reduce the intensity of the South Asian summer monsoon and rainfall to some extent, but this influence is only obvious in early summer and almost disappears in later stages.  相似文献   

A Modeling Study of the Effects of Anomalous Snow Cover over the Tibetan Plateau upon the South Asian Summer Monsoon     

LIU Huaqiang  SUN Zhaobo  WANG Ju  MIN Jinzhong 《大气科学进展》2004,21(6):964-975

The effect of anomalous snow cover over the Tibetan Plateau upon the South Asian summer monsoon is investigated by numerical simulations using the NCAR regional climate model (RegCM2) into which gravity wave drag has been introduced. The simulations adopt relatively realistic snow mass forcings based on Scanning Multi-channel Microwave Radiometer (SMMR) pentad snow depth data. The physical mechanism and spatial structure of the sensitivity of the South Asian early summer monsoon to snow cover anomaly over the Tibetan Plateau are revealed. The main results are summarized as follows. The heavier than normal snow cover over the Plateau can obviously reduce the shortwave radiation absorbed by surface through the albedo effect, which is compensated by weaker upward sensible heat flux associated with colder surface temperature, whereas the effects of snow melting and evaporation are relatively smaller.The anomalies of surface heat fluxes can last until June and become unobvions in July. The decrease of the Plateau surface temperature caused by heavier snow cover reaches its maximum value from late April to early May. The atmospheric cooling in the mid-upper troposphere over the Plateau and its surrounding areas is most obvious in May and can keep a fairly strong intensity in June. In contrast, there is warming to the south of the Plateau in the mid-lower troposphere from April to June with a maximum value in May.The heavier snow cover over the Plateau can reduce the intensity of the South Asian summer monsoon and rainfall to some extent, but this influence is only obvious in early summer and almost disappears in later stages.  相似文献   

青藏高原积雪与亚洲季风环流年代际变化的关系   总被引：12，自引：1，他引：12  

刘华强  孙照渤  朱伟军 《南京气象学院学报》2003,26(6):733-739

利用高原测站的月平均雪深资料和NCEP／NCAR再分析资料，分析了20世纪70年代末以来，青藏高原积雪的显著增多与亚洲季风环流转变的联系。研究表明，高原南侧冬春季西风的增强及西风扰动的活跃是造成青藏高原冬春积雪显著增多的主要原因，高原积雪的增多与亚洲夏季风的减弱均是亚洲季风环流转变的结果；20世纪70年代末以来，夏季华东降水的增多、华南降水的减少及华北的干旱化与青藏高原冬春积雪增多及东亚夏季风的减弱是基本同步的，高原冬春积雪与华东夏季降水的正相关、与华北及华南夏季降水的负相关主要是建立在年代际时间尺度上，因此，高原积雪与我国夏季降水关系的研究应以亚洲季风环流的年代际变化为背景。  相似文献   

Using idealized snow forcing to test teleconnections with the Indian summer monsoon in the Hadley Centre GCM   总被引：2，自引：1，他引：1  

A. G. Turner  J. M. Slingo 《Climate Dynamics》2011,36(9-10):1717-1735

Anomalous heavy snow during winter or spring has long been regarded as a possible precursor of deficient Indian monsoon rainfall during the subsequent summer. However previous work in this field is inconclusive, in terms of the mechanism that communicates snow anomalies to the monsoon summer, and even the region from which snow has the most impact. In this study we explore these issues in coupled and atmosphere-only versions of the Hadley Centre model. A 1050-year control integration of the HadCM3 coupled model, which well represents the seasonal cycle of snow cover over the Eurasian continent, is analysed and shows evidence for weakened monsoons being preceded by strong snow forcing (in the absence of ENSO) over either the Himalaya/Tibetan Plateau or north/west Eurasia regions. However, empirical orthogonal function (EOF) analysis of springtime interannual variability in snow depth shows the leading mode to have opposite signs between these two regions, suggesting that competing mechanisms may be possible. To determine the dominant region, ensemble integrations are carried out using HadAM3, the atmospheric component of HadCM3, and a variety of anomalous snow forcing initial conditions obtained from the control integration of the coupled model. Forcings are applied during spring in separate experiments over the Himalaya/Tibetan Plateau and north/west Eurasia regions, in conjunction with climatological SSTs in order to avoid the direct effects of ENSO. With the aid of idealized forcing conditions in sensitivity tests, we demonstrate that forcing from the Himalaya region is dominant in this model via a Blanford-type mechanism involving reduced surface sensible heat and longwave fluxes, reduced heating of the troposphere over the Tibetan Plateau and consequently a reduced meridional tropospheric temperature gradient which weakens the monsoon during early summer. Snow albedo is shown to be key to the mechanism, explaining around 50% of the perturbation in sensible heating over the Tibetan Plateau, and accounting for the majority of cooling through the troposphere.  相似文献   

Interannual variability in the onset of the summer monsoon over the Eastern Bay of Bengal   总被引：3，自引：0，他引：3  

J. Mao  G. Wu 《Theoretical and Applied Climatology》2007,89(3-4):155-170

Summary Climatological characteristics associated with summer monsoon onset over the eastern Bay of Bengal (BOB) are examined in terms of the westerly-easterly boundary surface (WEB). The vertical tilt of the WEB depends on the horizontal meridional temperature gradient (MTG) near the WEB, under the constraint of the thermal wind balance. The switch in the WEB tilt firstly occurs between 90 and 100°E during the first pentad of May. At this time the 850 hPa ridgeline splits over the BOB and heavy rainfall commences over the eastern BOB, indicating the onset of the BOB summer monsoon (BOBSM). The area-averaged MTG (200–500 hPa) is proposed as an index to define the BOBSM onset. A comparison of the onset determined by the MTG, 850 hPa zonal wind, and outgoing longwave radiation (OLR) shows that the MTG index is the most effective in characterizing the interannual variability of the BOBSM onset. Strong precursor signals are found prior to an anomalous BOBSM onset. Composite results show that early (late) BOBSM onset follows excessive (deficient) rainfall over the western Pacific and anomalous lower tropospheric cyclonic circulation which extends zonally from the northern Indian Ocean into the western Pacific, and strong (weak) equatorial westerly anomalies in the preceding winter and spring. Prior to an early (late) BOBSM onset, significant positive (negative) thickness anomalies exist around the Tibetan Plateau, accompanied by anomalous upper tropospheric anticyclonic (cyclonic) circulation. The interannual variations of the BOBSM onset are significantly correlated with anomalous sea surface temperature related to ENSO. These occurs through changes in the Walker circulation and local Hadley circulation, leading to middle and upper tropospheric temperature anomalies over the Asian sector. The strong precursor signals around the Tibetan Plateau may be partly caused by local snow cover anomalies, and an early (late) BOBSM onset is preceded by less (more) snow accumulation over the Tibetan Plateau during the preceding winter.  相似文献   

青藏高原冬春季积雪异常对中国春夏季降水的影响   总被引：27，自引：3，他引：27  

钱永甫张艳  郑益群 《干旱气象》2003,21(3):1-7

利用1956年12月～1998年12月共42a，青藏高原及其附近地区78个积雪观测站的雪深和我国160站月降水的距平资料，分析了其气候特征，并用SVD方法分析了冬春季积雪异常与春夏季我国降水异常的关系。用区域气候模式RegCM2模拟了青藏高原积雪异常的气候效应并检验了诊断分析的结果。分析表明，雪深异常，尤其是冬季雪深异常是影响中国降水的一个因子。研究证明，高原冬季雪深异常对后期中国区域降水的影响比春季雪深异常的影响更为重要。数值模拟的结果表明，高原雪深和雪盖的正异常推迟了东亚夏季风的爆发日期，减弱了季风强度，造成华南和华北降水减少，而长江和淮河流域降水增加。冬季雪深异常比冬季雪盖异常和春季雪深异常对降水的影响更为显著。机理分析指出，高原及其邻近地区的积雪异常首先通过融雪改变土壤湿度和地表温度，从而改变了地面到大气的热量、水汽和辐射通量。由此所引起的大气环流变化又反过来影响下垫面的特征和通量输送。在湿土壤和大气之间，这样一种长时间的相互作用是造成后期气候变化的关键过程。与干土壤和大气的相互作用过程有本质差别。  相似文献   

青藏高原云-辐射-加热效应和南亚夏季风--1985年与1987年对比分析   总被引：4，自引：0，他引：4  

王可丽  吴国雄  江灏  刘平 《气象学报》2002,60(2):173-180

文中首先利用NCEP NCAR再分析的风场资料 ,分析了南亚夏季风的时空特征 ,选取了有代表性的典型强、弱夏季风年 ,继而利用ISCCP C2、ERBE S4卫星观测资料和NCEP NCAR再分析资料 ,对比分析了强、弱夏季风前期青藏高原地区的云—辐射—加热状况及其在海、陆差异中的作用。分析结果表明 ,南亚夏季风强或弱 ,其前期青藏高原地区的云—辐射—加热效应有明显的差异。在强 (弱 )南亚夏季风的前期 ,青藏高原大部分地区为相对少 (多 )云区 ,其云量变化不仅表明了此区的云—辐射—加热效应的不同 ,更重要的是与此同时出现的海、陆之间云量分布的“跷跷板”现象 ,进一步改变了海、陆之间的热力差异。而且 ,在强南亚夏季风年 ,这种热力差异不但开始得早 ,而且持续时间长、作用范围大 ,从而对南亚夏季风的形成和变化产生重要的影响  相似文献   

Recent Progress in the Impact of the Tibetan Plateau on Climate in China   总被引：14，自引：0，他引：14  

刘屹岷  包庆  段安民  钱正安  吴国雄 《大气科学进展》2007,24(6):1060-1076

Studies of the impacts of the Tibetan Plateau （TP） on climate in China in the last four years are reviewed. It is reported that temperature and precipitation over the TP have increased during recent decades. From satellite data analysis, it is demonstrated that most of the precipitation over the TP is from deep convection clouds. Moreover, the huge TP mechanical forcing and extraordinary elevated thermal forcing impose remarkable impacts upon local circulation and global climate. In winter and spring, stream flow is deflected by a large obstacle and appears as an asymmetric dipole, making East Asia much colder than mid Asia in winter and forming persistent rainfall in late winter and early spring over South China. In late spring, TP heating contributes to the establishment and intensification of the South Asian high and the abrupt seasonal transition of the surrounding circulations. In summer, TP heating in conjunction with the TP air pump cause the deviating stream field to resemble a cyclonic spiral, converging towards and rising over the TP. Therefore, the prominent Asian monsoon climate over East Asia and the dry climate over mid Asia in summer are forced by both TP local forcing and Eurasian continental forcing.
Due to the longer memory of snow and soil moisture, the TP thermal status both in summer and in late winter and spring can influence the variation of Eastern Asian summer rainfall. A combined index using both snow cover over the TP and the ENSO index in winter shows a better seasonal forecast.
On the other hand, strong sensible heating over the Tibetan Plateau in spring contributes significantly to anchor the earliest Asian monsoon being over the eastern Bay of Bengal （BOB） and the western Indochina peninsula. Qualitative prediction of the BOB monsoon onset was attempted by using the sign of meridional temperature gradient in March in the upper troposphere, or at 400 hPa over the TP. It is also demonstrated by a numerical experiment and theoretical study that the heating over the TP lea  相似文献