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1.
《高原气象》2016,(5)
为认识华北夏季降水异常原因及改进气候预测技术,利用华北夏季降水资料和NCEP/NCAR再分析大气环流等资料,并采用经向风场定义东亚夏季风指数,对东亚夏季风与华北夏季降水的关系进行了综合分析。结果表明:(1)通常在强东亚夏季风年华北夏季降水偏多,在弱东亚夏季风年华北夏季降水偏少。但也有相反的情况,强东亚夏季风年降水偏多(少)的空间分布形势与弱东亚夏季风年降水偏多(少)分布明显不同。(2)无论强东亚夏季风年还是弱东亚夏季风年,华北夏季降水偏多的环流条件是有充足的水汽来源(强夏季风年为西南风水汽输送异常,弱夏季风年为东南风水汽输送异常)和较好的动力上升条件(850 hPa层在华北有辐合环流,500 hPa层中纬度纬向环流突出,华北多低槽过境)。(3)华北夏季降水偏少的环流形势明显不同:在强夏季风年虽然有充足的水汽来源(西南风异常),在弱夏季风年水汽来源不足(偏北风异常),但都缺乏有效的动力上升条件(850 hPa层在华北为辐散环流,500 hPa层中纬度经向环流突出,华北低槽过境偏少)。(4)在强东亚夏季风年,尽管水汽来源充足,但由于动力上升条件不同而造成华北夏季降水量在不同年份有明显差别。如果动力上升条件好,华北夏季降水会异常偏多,反之,华北夏季降水也会出现异常偏少。(5)在弱东亚夏季风年,西南风水汽来源大量减少,如果又缺乏其它路径水汽补充,加上动力条件弱,华北夏季降水会异常偏少。弱夏季风年西南风水汽来源大量减少,但只要东南风水汽输送加强,华北仍会有足够的水汽来源,这时,如果有较好的动力上升条件,华北夏季仍然会出现降水异常偏多的情况,如2011-2013年。预测华北夏季降水不能简单认为东亚夏季风强、华北夏季降水就多,东亚夏季风弱、华北夏季降水就少,东亚夏季风强度变化只是说明了水汽条件不同,还应结合动力条件变化才能作好华北夏季降水气候预测。 相似文献
2.
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
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
3.
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
4.
贝加尔湖南侧大陆高压与东亚夏季风和中国夏季气候的关系 总被引:4,自引:0,他引:4
利用NCEP/NCAR再分析逐日500 hPa高度场资料,尝试对夏季亚洲中纬度出现的大陆高压(脊)进行统计分析。结果表明:50 a夏季大陆高压以维持日数在3 d及以上的占绝大多数;大陆高压存在较明显的年代际变化,其中在贝加尔湖南侧(35~55°N,90~105°E)区域的大陆高压自20世纪70年代末期以来异常偏多,尤其在7和8月。这正与气候突变后我国北方干旱的频繁发生相对应,说明大陆高压的异常活动与中国的气候年代际异常有密切的关系。运用NCEP/NCAR再分析月平均高度、势函数、风场和我国160站月降水、气温资料,分析了贝加尔湖南侧大陆高压与东亚夏季风环流和我国夏季气候的关系。结果表明:大陆高压正异常年,东亚Hadley环流偏强,导致贝加尔湖南侧发生异常偏强的下沉运动,在我国东部的低层存在北风异常;高低纬环流相互作用削弱了东亚夏季风,与其相联系的季风水汽输送减弱,造成我国夏季长江以北大部分地区水汽通量散度正异常,华北大部降水偏少,长江流域降水偏多,中国北方地区气温偏高。 相似文献
5.
《高原气象》2020,(4)
黑碳气溶胶的辐射强迫及其对东亚的气候效应仍有较大不确定性,同时在黑碳气溶胶气候效应的研究中对海洋的关注较少。为了量化分析黑碳气溶胶直接辐射效应和分析其通过海气相互作用对东亚夏季风的影响,用区域海气耦合模式进行黑碳气溶胶离线模拟的敏感试验。试验结果表明:东亚晴空大气顶和地面的净辐射强迫在春季分别为1. 58 W·m~(-2)和~(-2). 75 W·m~(-2),在夏季分别为1. 68 W·m~(-2)和~(-2). 62 W·m~(-2)。受黑碳气溶胶辐射效应影响,大气变暖,大气热力稳定度增加,云量减少。春季黑碳气溶胶的"热泵效应"引起华南降水增加和夏季风提前爆发。夏季孟加拉湾海表降温,南支槽加深,引起华南降水增加;另外中纬度附近经向温度梯度增大,进而增强冷空气势力和水汽辐散,引起华北降水减少。华南降水正异常和华北降水负异常有利于"南涝北旱"。黑碳气溶胶辐射效应能通过海气相互作用增加热带海表温度,减小经向温度梯度和海陆热力差异,进而减弱夏季风。此外,黑碳气溶胶辐射效应也能增强局域哈德莱环流及北风,进而减弱夏季风。 相似文献
6.
华北夏季大气水汽输送特征及其与夏季旱涝的关系 总被引:9,自引:2,他引:7
本文利用ECMWF再分析资料ERA40和中国160站的降水资料,分析了我国华北地区1958年-2002年夏季的大气水汽含量和水汽输送的基本气候特征,研究了华北夏季旱涝年的大气水汽含量和水汽输送异常情况,最后利用线性回归的方法探讨了该地区大气水汽含量和水汽输送的变化趋势.结果表明:华北地区夏季降水的大气水汽来源主要有3支:来自孟加拉湾的水汽、来自我国南海和西太平洋的水汽以及中高纬西风带的水汽输送.华北地区对流层低层以经向水汽输送通量为主,到了中高层则以纬向输送通量为主;与华北地区夏季旱涝密切相关的异常水汽输送主要是南海和西太平洋以及西风带水汽输送异常,华北地区南边界水汽输入异常和东边界水汽输出异常是造成华北夏季旱涝年水汽收支异常的主要原因;近半个世纪以来,伴随着华北干旱化的加剧,华北地区南边界输入的大气水汽呈现显著的减少趋势. 相似文献
7.
华北夏季降水的年代际趋势突变及其可能成因 总被引:3,自引:0,他引:3
施晓晖 《高原山地气象研究》2008,28(2):22-28
介绍了一种最新的分段线性拟合检验气候变化趋势突变点的方法,并利用该方法对1968-2000年华北地区夏季降水年代际时间尺度的趋势突变点进行了检验,结果表明在年代际时间尺度条件下,华北夏季降水在1977年前后发生了趋势突变,500 hPa位势高度距平场在突变前后基本上呈“反向”分布。与趋势估计方法比较,分段线性拟合方法可以明确地给出趋势突变点的位置,物理意义更加合理,具有较大的优越性。分析年代际趋势突变前后水汽输送和地面感热通量的变化,发现突变前后,中国东部的西南水汽输送由强转弱,而突变前后春、夏季地表感热通量的变化使得大陆东南部的海陆热力差异由强转弱,可能导致东亚夏季风环流由强变弱,进而削弱华北的水汽输送,使华北夏季降水出现减少趋势。 相似文献
8.
春夏东亚大气环流年代际转折的影响及其可能机理 总被引:2,自引:0,他引:2
本文通过多变量联合经验正交分解(MV-EOF)方法揭示了近30年(1979~2010年) 春季和夏季东亚大气环流所发生的年代际转折及其与中国南方降水年代际季节反相变化的内在联系,探讨了局地性大气热源年代际变化影响东亚大气环流年代际转折的可能机理.结果表明:(1)东亚大气环流春季第一模态和夏季第二模态在90年代中期都发生了明显的年代际转折;(2)与春季大气环流第一模态和夏季大气环流第二模态年代际转折相对应的是中国南方降水明显的年代际季节反相变化,即春季降水年代际减少,夏季降水年代际增多;(3)春季青藏高原和夏季贝加尔湖地区大气热源年代际变化对东亚大气环流年代际转折有一定贡献,是造成中国南方降水年代际季节反相变化的直接原因;(4)春季青藏高原大气热源的年代际减弱,使得高原东南侧的西南风减弱,导致中国南方上空水汽输送不足,春季降水减少.夏季贝加尔湖大气热源偶极型分布由“南负北正”转变为“南正北负”,由此在贝湖上空激发高压异常,使得夏季雨带北进受阻而停滞南方,造成中国南方夏季降水增多. 相似文献
9.
10.
利用法国动力气象实验室发展的高分辨可变网格大气环流模式LMDZ,分别通过LMDZ的高分辨可变网格区域版及其全球版模式的数值模拟,研究长三角城市群下垫面变化带来的夏季气候效应,并尝试探讨大尺度环流的响应.其中LMDZ高分辨区域模式的模拟结果表明长三角城市群下垫面变化可导致夏季长三角地区接受的净辐射明显增加,感热通量上升,潜热通量下降,引起局地地表温度显著上升.同时西太平洋副热带高压西伸北抬控制长三角地区,反气旋性水汽通量异常,导致该地区降水异常减少.进一步对LMDZ全球模式的模拟结果分析,发现长三角城市群下垫面变化可能会引起大气基本模态的变化,进而引起南北半球中高纬异常波列结构的出现. 相似文献
11.
Using the monthly NCEP-NCAR reanalysis dataset, the monthly temperature and precipitation
at surface stations of China, and the MM5 model, we examine impacts of vegetation cover changes in
western China on the interdecadal variability of the summer climate over northwestern China during
the past 30 years. It is found that the summer atmospheric circulation, surface air temperature,
and rainfall in the 1990s were different from those in the 1970s over northwestern China, with
generally more rainfall and higher temperatures in the 1990s. Associated with these changes, an
anomalous wave train appears in the lower troposphere at the midlatitudes of East Asia and the
low-pressure system to the north of the Tibetan Plateau is weaker. Meanwhile, the South Asian
high in the upper troposphere is also located more eastward. Numerical experiments show that
change of vegetation cover in western China generally forces anomalous circulations and
temperatures and rainfall over these regions. This consistency between the observations and
simulations implies that the interdecadal variability of the summer climate over northwestern
China between the 1990s and 1970s may result from a change of vegetation cover over western
China. 相似文献
12.
The ability of seven global coupled ocean-atmosphere models to reproduce East Asian monthly surface temperature and precipitation climatologies during 1961 1990 is evaluated. January and July climate differences during the 2050s and 2090s relative to 1961-1990 projected by the seven-model ensemble under the Special Report on Emission Scenarios (SRES) A2 and B2 scenarios are then briefly discussed. These projections, together with the corresponding atmospheric CO2 concentrations under the SRES A2 and B2 scenarios, are subsequently used to drive the biome model BIOME3 to simulate potential vegetation distribution in China during the 2050s and 2090s. It is revealed that potential vegetation belts during the 2050s shift northward greatly in central and eastern China compared to those during 1961-1990. In contrast, potential vegetation change is slight in western China on the whole. The spatial pattern of potential vegetation during the 2090s is generally similar to that during the 2050s, but the range of potential vegetation change against 1961 1990 is more extensive during the 2090s than the 2050s, particularly in western China. Additionally, there exists model-dependent uncertainty of potential vegetation change under the SRES A2 scenario during the 2090s, which is due to the scatter of projected climate change by the models. The projected change in potential vegetation under the SRES A2 scenario during the 2090s is attributable to surface temperature change south of 35°N and to the joint changes of surface temperature, precipitation, and atmospheric CO2 concentration north of 35°N. 相似文献
13.
MM5 Simulations of the China Regional Climate During the LGM.II: In
uence of Change of Land Area, Vegetation, and Large-scale Circulation Background 
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下载免费PDF全文 Using a regional climate model MM5 nested to an atmospheric global climate model CCM3, a series of simulations and sensitivity experiments have been performed to investigate the relative LGM climate response to changes of land-sea distribution, vegetation, and large-scale circulation background over China.Model results show that compared with the present climate, the fluctuations of sea-land distribution in eastern Asia during the LGM result in the temperature decrease in winter and increase in summer. It has significant impact on the temperature and precipitation in the east coastal region of China. The impact on precipitation in the east coastal region of China is the most significant one, with 25%-50% decrease in the total precipitation change during the LGM. On the other hand, the changes in sea-land distribution have less influence on the climate of inland and western part of China. During the LGM, significant changes in vegetation result in temperature alternating with winter increase and summer decrease, but differences in the annual mean temperature are minor. During the LGM, the global climate, i.e., the large-scale circulation background has changed signi cantly. These changes have signi cant influences on temperature and precipitation over China. They result in considerable temperature decreases in this area, and direct the primary patterns and characteristics of temperature changes. Results display that, northeastern China has the greatest temperature decrease, and the temperature decrease in the Tibetan Plateau is larger than in the eastern part of China located at the same latitude. Moreover, the change of large-scale circulation background also controls the pattern of precipitation change. Results also show that, most of the changes in precipitation over western and northeastern parts of China are the consequences of changing large-scale circulation background, of which 50%-75% of precipitation changes over northern and eastern China are the results of changes in large-scale circulation background. Over China, the LGM climate responses to di erent mechanisms in order of strength from strong to weak are, the large-scale circulation pattern, sealand distribution, vegetation, CO2 concentration, and earth orbital parameters. 相似文献
14.
Responses of vegetation distribution to climate change in China 总被引:1,自引:1,他引:0
Climate plays a crucial role in controlling vegetation distribution and climate change may therefore cause extended changes. A coupled biogeography and biogeochemistry model called BIOME4 was modified by redefining the bioclimatic limits of key plant function types on the basis of the regional vegetation–climate relationships in China. Compared to existing natural vegetation distribution, BIOME4 is proven more reliable in simulating the overall vegetation distribution in China. Possible changes in vegetation distribution were simulated under climate change scenarios by using the improved model. Simulation results suggest that regional climate change would result in dramatic changes in vegetation distribution. Climate change may increase the areas covered by tropical forests, warm-temperate forests, savannahs/dry woodlands and grasslands/dry shrublands, but decrease the areas occupied by temperate forests, boreal forests, deserts, dry tundra and tundra across China. Most vegetation in east China, specifically the boreal forests and the tropical forests, may shift their boundaries northwards. The tundra and dry tundra on the Tibetan Plateau may be progressively confined to higher elevation. 相似文献
15.
LIU Yu HE Jinhai LI Weiliang CHEN Longxun LI Wei ZHANG Bo 《Acta Meteorologica Sinica》2010,24(4):468-483
Using a regional climate model MM5 nested with an atmospheric global climate model CCM3, a series of simulations and sensitivity experiments have been performed to investigate responses of the mid-Holocene climate to different factors over China. Model simulations of the mid-Holocene climate change, especially the precipitation change, are in good agreement with the geologic records. Model results show that relative to the present day (PD) climate, the temperature over China increased in the mid-Holocene, and the increase in summer is more than that in winter. The summer monsoon strengthened over the eastern China north of 30°N, and the winter monsoon weakened over the whole eastern China; the precipitation increased over the west part of China, North China, and Northeast China, and decreased over the south part of China.The sensitive experiments indicate that changes in the global climate (large-scale circulation background),vegetation, earth orbital parameter, and CO2 concentration led to the mid-Holocene climate change relative
to the PD climate, and changes in precipitation, temperature and wind fields were mainly affected by change of the large-scale circulation background, especially with its effect on precipitation exceeding 50%. Changes in vegetation resulted in increasing of temperature in both winter and summer over China, especially over eastern China; furthermore, its effect on precipitation in North China accounts for 25% of the total change.Change in the orbital parameter produced the larger seasonal variation of solar radiation in the mid-Holocene than the PD, which resulted in declining of temperature in winter and increasing in summer; and also had
an important effect on precipitation with an effect equivalent to vegetation in Northeast China and North China. During the mid-Holocene, CO2 content was only 280×10-6, which reduced temperature in a very small magnitude. Therefore, factors affecting the mid-Holocene climate change over China from strong to weak are large-scale circulation pattern, vegetation, earth orbital parameter, and CO2 concentration. 相似文献
16.
中国农田下垫面变化对气候影响的模拟研究 总被引:1,自引:0,他引:1
使用同期的美国国家环境预报中心/能源部(NCEP/DOE)再分析资料驱动区域气候耦合模式AVIM-RIEMS2.0,从遥感卫星图像资料中获取3期中国土地利用/覆盖数据中的农田植被类型,将其分别引入到AVIM-RIEMS2.0模式进行积分,研究中国农田下垫面变化对东亚区域气候的影响。结果表明:中国农田变化对气候影响具有冬季弱、夏季强的季节性变化,夏季气温和降水的差异在一些地区通过了95%的显著性检验;20世纪80年代农田扩张,林地、草地为主的植被类型转化为农田,植被变化区域的叶面积指数降低,反照率升高,且通过了95%的显著性检验,使得中国东部地区的气温由南到北呈现增加—减少—增加—减少的相间变化趋势,而降水的变化趋势大体相反;20世纪90年代农田面积减少,除东北地区外,农田变化引起的植被变化与80年代基本相反,叶面积指数变化、反照率以及由此导致的气候各要素也呈现大体相反的变化趋势;不同时期农田变化引起的植被类型转化的差异,使850 hPa风场变化趋势基本相反,可能是导致气温和降水变化趋势差异的主要原因之一。 相似文献
17.
利用动态植被模型CLM4-CNDV、区域气候模式RegCM4.6-CLM3.5和全球气候模式CAM4探究了当前气候状态下东亚区域可能的自然植被分布以及自然植被恢复对东亚区域气候产生的可能影响。结果表明,当前气候条件下,农作物区可能分布的自然植被为:蒙古高原以北、东北、华北平原和四川盆地的部分地区为裸土;东亚东南部及蒙古高原以北地区主要为林地;四川盆地及山东半岛主要为灌木;东北地区、东南沿海和长江中下游地区主要为草地。将农作物区恢复为自然植被后将对区域气候产生显著影响。其中,东亚东部大部分地区由于植被叶面积指数增加引起的蒸散发增强,使得夏季降水增加且温度降低显著;华北、四川盆地和广东中部平原地区植被叶面积指数减小,伴随区域内夏季降水显著减少且温度升高。而蒙古高原地区的气候变化不仅受区域内植被覆盖变化影响,还可能与印度地区和我国东南部植被变化引起的大气环流调整有关,使得蒙古高原西部冬季温度降低,而其东部夏季温度升高,同时夏季降水减少显著。研究所采用的试验方案是在相对理想的情况下进行的,但其结果为进一步区分不同地区植被覆盖变化的影响提供一定的参考。 相似文献
18.
The Decadal Shift of the Summer Climate in the Late 1980s over Eastern China and Its Possible Causes 总被引:2,自引:0,他引:2 下载免费PDF全文
下载免费PDF全文 In this paper, it is pointed out that a notable decadal shift of, the summer climate in eastern China occurred in the late 1980s. In association with this decadal climate shift, after the late 1980s more precipitation appeared in the southern region of eastern China (namely South China), the western Pacific subtropical high stretched farther westward with a larger south-north extent, and a strengthened anticyclone at 850 hPa appeared in the northwestern Pacific. The decadal climate shift of the summer precipitation in South China was accompanied with decadal changes of the Eurasian snow cover in boreal spring and sea surface temperature (SST) in western North Pacific in boreal summer in the late 1980s. After the late 1980s, the spring Eurasian snow cover apparently became less and the summer SST in western North Pacific increased obviously, which were well correlated with the increase of the South China precipitation. The physical processes are also investigated on how the summer precipitation in China was affected by the spring Eurasian snow cover and summer SST in western North Pacific. The change of the spring Eurasian snow cover could excite a wave-train in higher latitudes, which lasted from spring to summer. Because of the wave-train, an abnormal high appeared over North China and a weak depression over South China, leading to more precipitation in South China. The increase of the summer SST in the western North Pacific reduced the land-sea thermal contrast and thus weakened the East Asian summer monsoon, also leading to more precipitation in South China. 相似文献
19.
中国东部夏季气候20世纪80年代后期的年代际转型及其可能成因 总被引:27,自引:7,他引:20
指出了中国东部夏季气候在20世纪80年代末出现了一次明显的年代际气候转型.伴随着这次年代际转型,80年代末以后中国东部南方地区降水明显增多,500 hPa西太平洋副热带高压西伸且南北范围变大,西北太平洋上空850 hPa反气旋增强.中国东部夏季80年代后期出现南方多雨的年代际转型与欧亚大陆春季积雪、西北太平洋夏季海面温度的年代际变化存在密切联系,它们也都在80年代末出现年代际转型.从80年代末以后,伴随着欧亚大陆春季积雪明显减少和西北太平洋夏季海面温度明显增高,中国夏季南方降水明显增加.文中分析了欧亚大陆春季积雪和西北太平洋夏季海面温度影响中国降水的物理过程,指出欧亚大陆春季积雪能够在500 hPa激发出大气中的遥相关波列,所激发出的波列可以从春季一直持续到夏季,造成中国北方为高压控制,南方为微弱低压控制,使得降水出现在中国南方.西北太平洋夏季海面温度的升高能够减小海陆热力差异,使得夏季风减弱,导致中国南方地区降水增多. 相似文献
20.
The relation of vegetation over the Tibetan Plateau to rainfall in China during the boreal summer 总被引:5,自引:0,他引:5
The relationship between vegetation on the Tibetan Plateau (TP) and summer (June–August) rainfall in China is investigated using the normalized difference vegetation index (NDVI) from the Earth Resources Observation System and observed rainfall data from surface 616 stations in China for the period 1982–2001. The leading mode of empirical orthogonal functions analysis for summer rainfall variability in China shows a negative anomaly in the area from the Yangtze River valley to the Yellow River valley (YYR) and most of western China, and positive anomalies in southern China and North China. This mode is significantly correlated with summer NDVI around the southern TP. This finding indicates that vegetation around the southern TP has a positive correlation with summer rainfall in southern China and North China, but a negative correlation with summer rainfall in YYR and western China. We investigate the physical process by which vegetation change affects summer rainfall in China. Increased vegetation around the southern TP is associated with a descending motion anomaly on the TP and the neighboring area to the east, resulting in reduced surface heating and a lower Bowen ratio, accompanied by weaker divergence in the upper troposphere and convergence in the lower troposphere on the TP. In turn, these changes result in the weakening of and a westward shift in the southern Asian High in the upper troposphere and thereby the weakening of and an eastward withdrawal in the western Pacific subtropical high. These features result in weak circulation in the East Asian summer monsoon. Consequently, enhanced summer rainfall occurs in southern China and North China, but reduced rainfall in YYR. 相似文献