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1.
Arti B. Bandgar J. S. Chowdary C. Gnanaseelan 《Theoretical and Applied Climatology》2014,118(1-2):69-79
The Northwest Pacific (NWP) circulation (subtropical high) is an important component of the East Asian summer monsoon system. During summer (June–August), anomalous lower tropospheric anticyclonic (cyclonic) circulation appears over NWP in some years, which is an indicative of stronger (weaker) than normal subtropical high. The anomalous NWP cyclonic (anticyclonic) circulation years are associated with negative (positive) precipitation anomalies over most of Indian summer monsoon rainfall (ISMR) region. This indicates concurrent relationship between NWP circulation and convection over the ISMR region. Dry wind advection from subtropical land regions and moisture divergence over the southern peninsular India during the NWP cyclonic circulation years are mainly responsible for the negative rainfall anomalies over the ISMR region. In contrast, during anticyclonic years, warm north Indian Ocean and moisture divergence over the head Bay of Bengal-Gangetic Plain region support moisture instability and convergence in the southern flank of ridge region, which favors positive rainfall over most of the ISMR region. The interaction between NWP circulation (anticyclonic or cyclonic) and ISMR and their predictability during these anomalous years are examined in the present study. Seven coupled ocean–atmosphere general circulation models from the Asia-Pacific Economic Cooperation Climate Center and their multimodel ensemble mean skills in predicting the seasonal rainfall and circulation anomalies over the ISMR region and NWP for the period 1982–2004 are assessed. Analysis reveals that three (two) out of seven models are unable to predict negative (positive) precipitation anomalies over the Indian subcontinent during the NWP cyclonic (anticyclonic) circulation years at 1-month lead (model is initialized on 1 May). The limited westward extension of the NWP circulation and misrepresentation of SST anomalies over the north Indian Ocean are found to be the main reasons for the poor skill (of some models) in rainfall prediction over the Indian subcontinent. This study demonstrates the importance of the NWP circulation variability in predicting summer monsoon precipitation over South Asia. Considering the predictability of the NWP circulation, the current study provides an insight into the predictability of ISMR. Long lead prediction of the ISMR associated with anomalous NWP circulation is also discussed. 相似文献
2.
Large-scale Circulation Anomalies Associated with Interannual Variation in Monthly Rainfall over South China from May to August简 总被引:2,自引:0,他引:2
Interannual variation in summer rainfall over South China (SC) was investigated on the monthly timescale.It was found that monthly rainfall from May to August exhibits different features of variation,and the amounts are basically independent of each other.There is a significant negative correlation,however,between May and July SC rainfall,which is partially related to the developing phases of ENSO events.It was also found that stronger (weaker) lower-tropospheric winds over SC and the upstream parts are responsible for more (less) SC rainfall in every month from May to August.Despite this monthly consistent enhancement of horizontal winds,the wind anomalies exhibit distinct differences between May-June and July-August,due to the remarkable change in climatological winds between these two periods.More SC rainfall is associated with a lower-tropospheric anticyclonic anomaly over the SCS and the Philippine Sea in May and June,but with a cyclonic anomaly centered over SC in July and August. 相似文献
3.
The impact of strong (weak) intraseasonal oscillation (ISO) over South China Sea (SCS) and South Asia (SA) in summer on the SCS and SA summer monsoon and the summer rainfall in Eastern China are studied by using the NCEP-NCAR analysis data and the rainfall data of 160 stations in China from 1961 to 2010. It is found that the impacts are significantly different in different months of summer. The study shows that in June and July cyclonic (anticyclonic) atmospheric circulation over SCS and SA corresponds to strong (weak) ISO over SCS. In August, however, strong (weak) ISO over SCS still corresponds to cyclonic (anticyclonic) atmospheric circulation over SA. In June and August cyclonic (anticyclonic) atmospheric circulation over South Asia corresponds to strong (weak) ISO over SA while a strong (weak) ISO corresponds to anticyclonic (cyclonic) atmospheric circulation over SA in July. Besides, in June the strong (weak) ISO over SA corresponds to cyclonic (anticyclonic) atmospheric circulation over SCS, while in July and August the atmospheric circulation is in the same phase regardless of whether the ISO over SA is strong or weak. The impacts of the strong(weak)ISO over SCS on the rainfall of eastern China are similar in June and July, which favors less (more) rainfall in Yangtze-Huaihe Rivers basin but sufficient (deficient) rainfall in the south of Yangtze River. However, the impacts are not so apparent in August. In South Asia, the strong (weak) ISO in July results in less (more) rainfall in the south of Yangtze River but sufficient (deficient) rainfall in Yangtze-Huaihe Rivers basin. The influence on the rainfall in eastern China in June and August is not as significant as in July. 相似文献
4.
In the present reported work, we identified that there is a significant negative relationship between rainfall over South China (SC) and the East European Plain (EEP) in the months of July and August, and investigated the possible reason for this negative relationship. The correlation coefficients between SC and the EEP rainfall were calculated to be ?0.42 for July and ?0.35 for August, both significant at the 95 % confidence level. We report that a wave-like train of circulation anomalies and a pathway of wave-activity flux stretching from Europe to East China connect the anticyclonic anomaly over Europe and the cyclonic anomaly over central and southern China, which are responsible for less EEP rainfall and more SC rainfall. We suggest that the teleconnection between SC and EEP rainfall results from the extension of stationary Rossby waves in the mid-latitudes in the upper troposphere for both July and August. This stationary Rossby wave is contributed to by summer North Atlantic Oscillation (NAO) and its extension features are determined by the location and intensity of the climatological upper-tropospheric westerly jet. Furthermore, we found that there was an interdecadal change around the mid-1970s in the negative SC–EEP rainfall relationship for both July and August. The negative correlation was significant and strong in the period 1976–2005, but much weaker in the period 1955–1975. The extension of stationary Rossby waves from Europe to East China was responsible for the significant negative relationship during the period 1976–2005. 相似文献
5.
This study investigates the circulation and precipitation anomalies associated with different configurations of the western North Pacific subtropical high(WNPSH) and the East Asian westerly jet(EAJ) in summer on interannual timescales. The in-phase configuration of the WNPSH and EAJ is characterized by the westward(eastward) extension of the WNPSH and the southward(northward) shift of the EAJ, which is consistent with the general correspondence between their variations. The out-of-phase configuration includes the residual cases. We find that the in-phase configuration manifests itself as a typical meridional teleconnection. For instance, there is an anticyclonic(cyclonic) anomaly over the tropical western North Pacific and a cyclonic(anticyclonic) anomaly over the mid-latitudes of East Asia in the lower troposphere. These circulation anomalies are more conducive to rainfall anomalies over the Yangtze River basin and south Japan than are the individual WNPSH or EAJ. By contrast, for the out-of-phase configuration, the mid-latitude cyclonic(anticyclonic) anomaly is absent, and the lower-tropospheric circulation anomalies feature an anticyclonic(cyclonic)anomaly with a large meridional extension. Correspondingly, significant rainfall anomalies move northward to North China and the northern Korean Peninsula. Further results indicate that the out-of-phase configuration is associated with the developing phase of ENSO, with strong and significant sea surface temperature(SST) anomalies in the tropical central and eastern Pacific which occur simultaneously during summer and persist into the following winter. This is sharply different from the in-phase configuration, for which the tropical SSTs are not a necessity. 相似文献
6.
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
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
7.
冬季热带西太平洋海平面气压与后期亚洲夏季风的关系 总被引:1,自引:0,他引:1
利用月平均的NCEP/NCAR再分析资料(1958-1996),基于一个新的冬季热带西太平区域环流指数,研究了冬季热带西太平洋环流的极端异常及其随时间的演变。研究发现,冬季热带西太平洋环流异常与北半球亚洲大陆高纬度地区的气候变化有紧密的联系。随着季节发展,冬季出现在热带西太平洋的一个反气旋(气旋)环流异常逐渐向东北方向移动并向西扩展,其东西方向的轴线逐渐被拉长。因此,位于反气旋(气旋)环流异常南部的异常东风(西风)连续向西伸展到印度半岛,导致南亚夏季风减弱(增强)。同时,随着季节发展,源于热带西太平洋的气压异常逐渐移近并最终占据亚洲大陆,进而影响夏季亚洲大陆热低压。 相似文献
8.
Influence of North Atlantic sea surface temperature (SST) anomalies on tropical Pacific SST anomalies is examined. Both summer and winter North Atlantic SST anomalies are negatively related to central-eastern tropical Pacific SST anomalies in the subsequent months varying from 5 to 13?months. In particular, when the North Atlantic is colder than normal in the summer, an El Ni?o event is likely to be initiated in the subsequent spring in the tropical Pacific. Associated with summer cold North Atlantic SST anomalies is an anomalous cyclonic circulation at low-level over the North Atlantic from subsequent October to April. Corresponded to this local response, an SST-induced heating over the North Atlantic produces a teleconnected pattern, similar to the East Atlantic/West Russia teleconnection. The pattern features two anticyclonic circulations near England and Lake Baikal, and two cyclonic circulations over the North Atlantic and near the Caspian Sea. The anticyclonic circulation near Lake Baikal enhances the continent northerlies, and strengthens the East-Asian winter monsoon. These are also associated with an off-equatorial cyclonic circulation in the western Pacific during the subsequent winter and spring, which produces equatorial westerly wind anomalies in the western Pacific. The equatorial westerly wind anomalies in the winter and spring can help initiate a Pacific El Ni?o event following a cold North Atlantic in the summer. 相似文献
9.
This study investigated the large-scale circulation anomalies, in both the upper and lower troposphere, associated with the interannual variation of rainfall in Pakistan during summer, using the station observation data in this country and circulation data of the NCEP?NCAR reanalysis from 1981 to 2017. Results showed that the upper- and lower-tropospheric circulation anomalies associated with monthly rainfall variability exhibit similar features from June to August, so analyses were performed on June?August circulation and Pakistan rainfall data. The analyzed results indicated that summer rainfall in Pakistan is enhanced when there is an anticyclonic anomaly to the northwest of Pakistan in the upper troposphere and easterly anomalies along the southern foothills of the Himalayas in the lower troposphere, and vice versa. These upper- and lower-tropospheric circulation anomalies were found to be related, but show unique features. The upper-tropospheric anticyclonic anomaly is closely related to the Silk Road Pattern along the Asian westerly jet, while the lower-tropospheric easterly anomalies are related to the cyclonic anomaly to the south of Pakistan, i.e., intensified South Asian monsoon trough. The results presented here suggest that the interannual variability of summer rainfall in Pakistan is a combined result of upper- and lower-tropospheric circulation anomalies, and of extratropical and tropical circulation anomalies. 相似文献
10.
The second EOF(EOF2) mode of interannual variation in summer rainfall over East China is characterized by inverse rainfall changes between South China(SC) and the Yellow River-Huaihe River valleys(YH).However,understanding of the EOF2 mode is still limited.In this study,the authors identify that the EOF2 mode physically depicts the latitudinal variation of the climatological summer-mean rainy belt along the Yangtze River valley(YRRB),based on a 160-station rainfall dataset in China for the period 1951-2011.The latitudinal variation of the YRRB is mostly attributed to two different rainfall patterns:one reflects the seesaw(SS) rainfall changes between the YH and SC(SS pattern),and the other features rainfall anomalies concentrated in SC only(SC pattern).Corresponding to a southward shift of the YRRB,the SS pattern,with above-normal rainfall in SC and below-normal rainfall in the YH,is related to a cyclonic anomaly centered over the SC-East China Sea region,with a northerly anomaly blowing from the YH to SC;while the SC pattern,with above-normal rainfall in SC,is related to an anticyclonic anomaly over the western North Pacific(WNP),corresponding to an enhanced southwest monsoon over SC.The cyclonic anomaly,related to the SS pattern,is induced by a near-barotropic eastward propagating wave train along the Asian upper-tropospheric westerly jet,originating from the mid-high latitudes of the North Atlantic.The anticyclonic anomaly,for the SC pattern,is related to suppressed rainfall in the WNP. 相似文献
11.
This study investigates summer rainfall variability in the South China Sea (SCS) region and the roles of remote sea surface temperature (SST) forcing in the tropical Indian and Pacific Ocean regions. The SCS summer rainfall displays a positive and negative relationship with simultaneous SST in the equatorial central Pacific (ECP) and the North Indian Ocean (NIO), respectively. Positive ECP SST anomalies induce an anomalous low-level cyclone over the SCS-western North Pacific as a Rossby-wave type response, leading to above-normal precipitation over northern SCS. Negative NIO SST anomalies contribute to anomalous cyclonic winds over the western North Pacific by an anomalous east–west vertical circulation north of the equator, favoring more rainfall over northern SCS. These NIO SST anomalies are closely related to preceding La Niña and El Niño events through the “atmospheric bridge”. Thus, the NIO SST anomalies serve as a medium for an indirect impact of preceding ECP SST anomalies on the SCS summer rainfall variability. The ECP SST influence is identified to be dominant after 1990 and the NIO SST impact is relatively more important during 1980s. These Indo-Pacific SST effects are further investigated by conducting numerical experiments with an atmospheric general circulation model. The consistency between the numerical experiments and the observations enhances the credibility of the Indo-Pacific SST influence on the SCS summer rainfall variability. 相似文献
12.
利用区域气候模式,分别以逐时海面温度(sea surface temperature, SST)数据及逐日SST数据作为模式的海表温度进行强迫,开展了1991~2010年共计20年的数值模拟,探讨SST日变化对中国区域气候变化的影响。对比结果表明,两组试验均能合理地再现中国区域气候的主要气候态特征。同时发现,两组试验模拟的气候特征在我国沿海区域以及近海洋面上存在明显差异:考虑SST日变化之后,2 m气温和感热通量差异呈现夏季(冬季)升高(降低)为主的趋势;潜热通量则与之相反;低层风场差异在夏季以海洋吹向大陆的东南风为主,冬季则以陆面吹向海洋的西北风差异为主;另外,水汽输送差异呈气旋式(反气旋式)时,降水出现正差异(负差异)。SST日变化对上述气候因子的影响在夏季更为显著。 相似文献
13.
华南4—5月持续性干旱及其环流背景 总被引:5,自引:1,他引:4
用测站降水量资料和NCEP-DOEⅡ再分析资料等,统计分析了华南春季各月降水量逐年变化的相互关系以及华南4—5月持续性干旱对应的大气环流异常特征,初步探讨了与华南4—5月持续性干旱有关的海温异常及其可能的影响机理。华南春季降水量主要变异型为全区一致型,近30年来华南春季降水量在减少,华南4、5月降水量的逐年变化有显著的同相特征。华南春旱主要是由4—5月的降水持续偏少造成的。在华南4—5月持续干旱年,华南附近高低空都存在一个异常的反气旋,并在华南上空造成异常下沉运动;东亚大槽南支偏弱,不利于中高纬度冷空气南下,因而不利于华南降水。在华南4—5月持续干旱年,热带中太平洋的海温正距平可从前一年12月一直持续到当年5月,其影响华南春旱的机制是:由于赤道中太平洋地区海温正距平,导致该区域的异常辐合上升运动,同时通过罗斯贝波的响应在其西侧即西太平洋赤道南、北两侧低空强迫形成气旋性环流异常,在菲律宾东侧的热带西太平洋上空强迫出异常的上升运动,进而使南海北部和华南地区出现异常的下沉运动,导致干旱;在南海及热带西太平洋上空大气低层出现的偏北风异常也使得来源于南海—西太平洋的水汽输送减弱,不利于华南降水。在华南4—5月持续干旱年,4、5月欧亚大陆中高纬度地区也存在一个持续性的西北—东南向的异常环流波列,其对华南干旱的发生也具有显著的影响作用。 相似文献
14.
利用1979—2007年NOAA重建海温逐月资料和中国160站夏季降水资料,使用扩展奇异值分解(extended singular value decomposition,ESVD)方法,研究了冬季热带太平洋海温异常与次年夏季中国降水异常季节内演变型之间的关系,指出前冬El Nino事件是与次年夏季中国降水季节内变化相联系的最重要的热带太平洋海温异常模态。相应的降水异常季节内变化情况为:6月在长江以南为正异常,江淮流域有负异常;7月在华南沿海有负降水异常,而正异常北进到长江流域,华北地区也出现正降水异常;8月在长江南北分别为少雨和多雨。进一步研究前冬El Nino事件与次年春夏印度洋、太平洋海温异常、对流层低层风场异常以及副热带高压等的联系,结果表明:El Nio事件发生的次年春夏,热带西太平洋周边存在东负西正的海温异常分布;西太平洋反气旋异常较强;副高在6月、7月偏西偏北,但在8月迅速南退。虽然与El Nino事件相联系的6月与7月、8月的降水型不同,但是西太平洋反气旋异常带来的充沛水汽造成7月长江流域雨季多雨,8月副高迅速南退带来的又一次长江流域降水,造成了El Nino事件发生次年夏季长江流域涝而华南沿海旱的夏季平均降水异常型。 相似文献
15.
副热带东南太平洋海温对东北夏季降水的影响及可能机制 总被引:1,自引:0,他引:1
诊断分析表明,前期副热带东南太平洋海温尤其是前春海温与东北夏季降水存在持续稳定的负相关关系。无论是在年际时间尺度还是年代际尺度上,冬、春、夏季海温演变趋势与降水均呈反位相。尺度分离结果显示,关键区海温与降水的显著负相关主要依赖于其年代际分量,但年际分量也起到较重要贡献。相关分析和合成分析结果都发现,当副热带东南太平洋海温偏低时,其上空可激发出反气旋式距平风场,而在关键区海域西北部激发出气旋式距平环流。同时在所罗门群岛和菲律宾南部分别出现反气旋式和气旋式距平环流。西太平洋副热带高压(副高)位置较常年偏西,副高区为反气旋式距平环流。在东北地区西侧则为气旋式距平环流。在这样的环流背景下,副高西侧的南风加强了源自南海和西太平洋的暖湿气流和北方冷空气在东北地区的交汇,从而使东北夏季多雨。反之,当东南太平洋海温偏高时,其激发的气旋及反气旋距平中心和偏低年刚好相反,副高位置偏东,其西侧的南方水汽输送偏弱,同时东北冷涡也偏弱,冷暖空气汇合形成的低空辐合弱,东北降水因此偏少。这表明,副热带东南太平洋海温异常时确实能激发出一个从关键海区到东北地区的跨越南北半球的气旋-反气旋交替波列,引发北半球中高纬度大气环流异常,从而影响东北夏季降水。 相似文献
16.
6月初,亚洲中高纬地区的气温迅速增暖后趋于稳定,大气环流由冬季环流转变为夏季环流。根据1951~2017年间各年亚洲中高纬地区春夏季节转换(以下简称季节转换)的时间,基于NCEP再分析资料和中国地区的观测资料,研究了季节转换发生早晚对梅雨期中国地区降水及环流的影响。在季节转换偏早(晚)年的梅雨期,对流层中层(500 hPa)高度距平场从东北亚中高纬、中国东北和日本以南地区出现“+ ? +”(“? + ?”)的经向波状结构。在850 hPa距平风场上,也有相近的波状结构。当东北亚脊偏强(弱)时,东北地区为气旋式(反气旋式)环流距平,西太平洋副热带为反气旋式(气旋式)距平。环流异常导致东北地区降水异常偏多(少),长江流域降水偏少(多)。本文还初步探讨了亚洲中高纬地区入夏时间的早晚如何影响梅雨期大气环流和中国东部降水异常的途径。在季节转换偏早(晚)年,东北亚高压脊建立较早(晚),强度偏强(弱),而且对应的东北亚脊异常往往可持续到梅雨期结束,从而有利于东亚沿岸 “+ ? +”(“? + ?”)经向波状环流及相应雨带的形成。 相似文献
17.
Summary The Southern South America climatological 500 hPa relative vorticity mean state was examined using regional objective analyses
of 500 hPa geopotential heights provided by the Servicio Meteorológico Nacional of Argentina. The dataset, covering the period
June 1983 to July 1987, was stratified into two samples: the cold and warm seasons. Mean cyclonic vorticity south of 40° S
results in a climatological trough over Patagonia with a northwest-southeast tilt. North of this latitude, mean anticyclonic
circulation dominates with the exception of a centre of cyclonic vorticity over the Río de la Plata (35° S, 56° W). Seasonal
changes appear to be small. Relative vorticity frequency distributions were also analysed.
The association between precipitation and synoptic-scale features of the mid-troposphere circulation was investigated through
vorticity fields. A particular distribution of vorticity anomalies associated with daily precipitation in Buenos Aires is
revealed by biserial correlation coefficient fields. In winter, the strongest relationships are found between 35° S and 40° S
over the Andes Mountains (minimum significant correlation coefficients indicating a cyclonic vorticity anomaly), and in the
south of Brazil and east of Buenos Aires over the Atlantic Ocean down to a latitude of 40° S (maximum correlation coefficients
related to anomalously anticyclonic circulation). This shows the preferential position of troughs and ridges that produce
precipitation in Buenos Aires on the time scale of a day. In summer, centres of anomalously cyclonic and anticyclonic vorticity
associated with precipitation shift slightly southward. For moderate or intense precipitation in Buenos Aires, advection of
warm and wet air southwards appears to be more important in winter, while in summer the strong anomalous vorticity gradient
north of the negative centre over the Andes Cordillera favours rainfall in Buenos Aires.
Received April 17, 1997 相似文献
18.
There is a well-known seesaw pattern of precipitation between the tropical western North Pacific(WNP) and the Yangtze River basin(YRB) during summer. This study identified that this out-of-phase relationship experiences a subseasonal change;that is, the relationship is strong during early summer but much weaker during mid-summer. We investigated the large-scale circulation anomalies responsible for the YRB rainfall anomalies on the subseasonal timescale. It was found that the YRB rainfall is mainly affected by the tropical circulation anomalies during early summer, i.e., the anticyclonic or cyclonic anomaly over the subtropical WNP associated with the precipitation anomalies over the tropical WNP. During mid-summer, the YRB rainfall is mainly affected by the extratropical circulation anomalies in both the lower and upper troposphere. In the lower troposphere, the northeasterly anomaly north of the YRB favors heavier rainfall over the YRB by intensifying the meridional gradient of the equivalent potential temperature over the YRB. In the upper troposphere, the meridional displacement of the Asian westerly jet and the zonally oriented teleconnection pattern along the jet also affect the YRB rainfall. The subseasonal change in the WNP–YRB precipitation relationship illustrated by this study has important implications for the subseasonalto-seasonal forecasting of the YRB rainfall. 相似文献
19.
冬季赤道西太平洋环流状况与后期亚洲季风 总被引:4,自引:0,他引:4
基于月平均NCEP再分析资料(1958~1997年)以及中国336个台站月降水总量(195l~1994年),通过合成、相关以及统计显著性检验方法,研究了赤道西太平洋区域冬季环流状况与后期春夏季亚洲(东亚和南亚)季风环流变化的关系.研究结果表明,冬季赤道西太平洋环流状况对后期南亚季风和东亚季风以及我国夏季降水均有显著的滞后影响.冬季赤道西太平洋海域海平面气压偏高(低),对应反气旋(气旋)性环流异常,致使后期东亚和南亚夏季风均偏弱(强)以及我国长江流域夏季降水偏多(少),揭示了实施这种滞后影响的一般特征. 相似文献
20.
This study investigates the influences of boreal summer intraseasonal oscillation (BSISO), which originates from the equatorial Indian Ocean and prevails over the Indo-Pacific region, on precipitation over Southeast China, including South China and Yangtze River Valley. The results indicate that the BSISO-related precipitation anomalies are remarkably different between early summer (May–June) and late summer (July–August). The BSISO-related precipitation anomalies tend to appear more northward in late summer in comparison with early summer. Accordingly, the BSISO is significantly related to precipitation anomalies over South China during many phases in early summer but related to very weak anomalies during all the phases in late summer. Such northward shifts of precipitation anomalies from early summer to late summer are clearest during phases 4 and 7, when the lower-tropospheric anticyclonic and cyclonic circulation anomalies dominate over the subtropical western North Pacific, respectively. Finally, we explain the differences between early and late summers through the seasonal northward migration of climatological equivalent potential temperature gradient, which is located in the South China during early summer but migrates northward to the YRV during late summer. 相似文献