共查询到20条相似文献,搜索用时 31 毫秒
1.
南海夏季风演变的气候学特征 总被引:17,自引:2,他引:17
本文总结南海北部地区夏季风演变的气候学特征,发现南海地区5月第3候对流层高层东风和北风爆发,对流层低层西风第1次跃升,东亚经向季风环流圈开始形成,这可以成为南海地区夏季风爆发的标志。对流层低层西风在6月中旬开始的第2次连续跃升对应江淮地区的梅雨爆发期。类似地,中国大陆夏季对流层低层5月初和6月初有两次爆发性增暖过程,第2次比第1次强烈得多。南海北部地区对流层低层纬向风速、比湿盛夏呈双峰型,纬向风速峰值分别出现在6月第5候和8月第4候,比湿峰值分别出现在6月第6候和8月第5候。比湿突升对应纬向风速突升,但略落后于风速峰值出现的时间。南海北部地区季风爆发前,温度是波动式上升的,南海季风爆发后,温度是波动式下降的。中国大陆东部及南海地区夏季对流层低层比湿分布有3次突变,即4月中旬南海北部比湿突增,并开始出现高比湿中心,而南海南部为最大比湿中心;5月中旬最大比湿中心已从南海南部跳到了南海北部-华南并向江淮流域扩展;6月中旬江淮流域比湿突增并一直维持到8月,同时南海南部高比湿带消失。而5月中旬OLR有一次突变,OLR低值区爆发性向北扩张,这对应于南海地区夏季风的爆发。而孟加拉湾地区夏季风演变的气候学特征与南海地区有较� 相似文献
2.
低平流层准两年变率研究 总被引:6,自引:2,他引:4
分析NCAR/NCEP40年分析资料得出,赤道低平流层纬向风年际变率的平均周期约28.2个月,最大振幅的20hPa,西(东)风距平平垂直下传平均速度1.21(1.04)km/月。用10hPa和70hPa月平均纬向风标准化距平之差反映整层准两年变率的相位。低平流层两半球中纬气温有与之配合的振荡,西(东)风切变时,中纬气温偏低(高)。赤道纬向风准两年变率引起的经圈环流异常是联系低续续向风与中纬气温准年 相似文献
3.
4.
华南前汛期的锋面降水和夏季风降水 I.划分日期的确定 总被引:7,自引:0,他引:7
前汛期暴雨常常引发华南地区的洪涝,但是前汛期降水的预报能力却相当低。降水的预报在很大程度上依赖于对降水性质的理解,而华南前汛期降水通常被认为只是锋面性质的降水。事实上,南海夏季风在6月(甚至5月)就可以影响到华南地区并产生季风对流降水。因此,华南前汛期包含了两种不同性质的降水,即锋面降水和夏季风降水,如何区分它们是非常重要的。为了区分它们,利用NCEP/NCAR再分析资料、CMAP资料和中国730站降水资料,分析气候平均(1971~2000年)状态下锋面降水和季风降水期间大气性质和特征的差异,得到华南前汛期夏季风降水开始的基本判据:100 hPa纬向风由西风转为东风并维持5天以上。利用该判据得出气候平均条件下的华南夏季风降水开始于5月24日,并得到1951~2004年逐年华南前汛期锋面降水和季风降水的划分日期。合成分析的结果表明,得到的划分日期是基本合理的,因为它将锋面降水和季风降水期间大气特点的显著差别区分开来。 相似文献
5.
利用WRF区域模式模拟分析了中南半岛地区春季土壤湿度异常对亚洲热带夏季风建立和发展的影响,结果表明:亚洲热带夏季风对中南半岛春季土壤湿度的响应是不对称的,当中南半岛春季土壤湿度偏高时,中南半岛及孟加拉湾周边地区呈现异常东风,伴随降水减少,季风减弱;而中南半岛春季土壤湿度偏低时,孟加拉湾及周边地区西风减弱,降水减少,季风也对应减弱。通过进一步分析物理机制得到,中南半岛春季土壤湿度异常偏高使季风建立初期感热减小,陆表温度明显降低,从而导致海陆温差逐渐降低,使季风减弱;而中南半岛春季土壤湿度异常偏低使整个中南半岛区域蒸发减少,导致地表向上输送的水汽减少,减弱季风环流和降水。此外,通过分析850 h Pa纬向风及对流层中上层经向温度梯度两项季风暴发指数,探讨了中南半岛春季土壤湿度异常对孟加拉湾东部季风暴发时间的影响,结果表明:中南半岛春季土壤湿度偏高时,孟加拉湾东部季风暴发时间大约推迟10天左右,而土壤湿度较低对亚洲热带夏季风暴发时间影响甚微。 相似文献
6.
Using the monthly geopotential heights and winds for 700 and 200 hPa for India during July and August, and the weekly M-100 Soviet rocketsonde temperature and wind data for Thumba (8.5oN, 76.9oE) during the last week of June and the first week of September for the two contrasting summer monsoon years 1975 (a very strong monsoon year) and 1979 (a very weak monsoon year), a study has been made to examine the mean circulation features of the troposphere over India, and the structures of the temperatures and the winds of the middle atmosphere over Thumba. The study suggested that the axis of the monsoon trough (AMT) at 700 hPa shifted southward in 1975 and northward towards the foothills of the Himalayas in 1979, from its normal position. Superimposed on the low-pressure area (AMT) at 700 hPa, a well-defined divergence was noticed at 200 hPa over the northern India in 1975.The mean temperatures, at 25,50 and 60 km (middle atmosphere) over Thumba were cooler in 1975 than in 1979. While a cooling trend in 1975 and warming trend in 1979 were observed at 25 and 50 km, a reversed picture was noticed at 60 km. There was a weak easterly/ westerly (weak westerly phase) zonal wind in 1975 and a strong easterly zonal wind in 1979. A phase reversal of the zonal wind was observed at 50 km. A tentative physical mechanism was offered, in terms of upward propagation of the two equatorially trapped planetary waves i.e. the Kelvin and the mixed Rossby-gravity waves, to explain the occurrence of the two spells of strong warmings in the mesosphere in 1975. 相似文献
7.
华西秋雨起止与秋冬季节大气环流转换 总被引:1,自引:0,他引:1
根据1961—2010年平均的逐候NCEP/NCAR再分析资料、1979—2008年平均的逐候CMAP降水资料以及1961—2010年逐候平均的中国553个台站降水资料,讨论了华西秋雨起止日期与秋冬季大气环流转换特征的关系。结果表明,华西地区降水年变化表现为明显的夏、秋双峰特征,8月4—8日(第44候)为双峰间的低谷,10月8—12日(第57候)以后降水降至年平均以下。由此,将华西秋雨建立和结束日期分别确定为8月9—13日(第45候)和10月8—12日(第57候)。华西秋雨的建立对应于东亚夏季风开始向冬季风转变,其标志性环流调整特征是江南地区的西南风转为东南风。东亚经向海平面气压梯度在8月9—13日(第45候)由南高北低转为南低北高,造成850 hPa江南地区的西南风转为东南风,该东南风与来自孟加拉湾的热带西南季风交汇于华西地区,形成风向和水汽的辐合,使得华西地区的降水在夏峰之后再次增强,华西秋雨由此建立。华西秋雨的结束则对应于孟加拉湾热带西南季风结束和东亚冬季风完全建立,其标志性环流调整特征是孟加拉湾地区的西南风转为东北风。随着东亚纬向海平面气压梯度由北向南依次发生东高西低向东低西高的转变,东亚冬季风也逐步向南推进,9月8—12日(第51候)东北冬季风到达江南地区,10月8—12日(第57候)进一步推进到南海地区,此时来自孟加拉湾的热带西南季风消失,造成华西地区完全受大陆冷高压控制,东亚季风经圈环流也转为冬季型哈得来环流,东亚冬季风完全建立,华西秋雨也随之结束。因此,华西秋雨起止可能与东亚夏季风、南亚夏季风向冬季风的转变时间不同步有关,东亚季风与南亚季风的共同作用使得华西秋雨成为亚洲夏季风在中国大陆上的最后一个雨季。 相似文献
8.
The Webster and Yang monsoon index (WYI)-the zonal wind shear between 850 and 200 hPa was calculated and modified on the basis of NCEP/NCAR reanalysis data. After analyzing the circulation and divergence fields of 150-100 and 200 hPa, however, we found that the 200-hPa level could not reflect the real change of the upper-tropospheric circulation of Asian summer monsoon, especially the characteristics and variation of the tropical easterly jet which is the most important feature of the upper-tropospheric circulation. The zonal wind shear U850-U(150 100) is much larger than U850-U200, and thus it can reflect the strength of monsoon more appropriately. In addition, divergence is the largest at 150 hPa rather than 200 hPa, so 150 hPa in the upper-troposphere can reflect the coupling of the monsoon system. Therefore, WYI is redefined as DHI, i.e., IDH=U850* - U(150 100)*, which is able to characterize the variability of not only the intensity of the center of zonal wind shear in Asia, but also the monsoon system in the upper and lower troposphere. DHI is superior to WYI in featuring the long-term variation of Asian summer monsoon as it indicates there is obvious interdecadal variation in the Asian summer monsoon and the climate abrupt change occurred in 1980. The Asian summer monsoon was stronger before 1980 and it weakened after then due to the weakening of the easterly in the layer of 150-100 hPa, while easterly at 200 hPa did not weaken significantly. After the climate jump year in general, easterly in the upper troposphere weakened in Asia, indicating the weakening of summer monsoon; the land-sea pressure difference and thermal difference reduced, resulting in the weakening of monsoon; the corresponding upper divergence as well as the water vapor transport decreased in Indian Peninsula, central Indo-China Peninsula, North China, and Northeast China, indicating the weakening of summer monsoon as well. The difference between NCEP/NCAR and ERA-40 reanalysis data in studying the intensity and long-term variation of Asian summer monsoon is also compared in the end for reference. 相似文献
9.
Global gridded daily mean data from the NCEP/NCAR Reanalysis(1948-2012) are used to obtain the onset date,retreat date and duration time series of the South China Sea summer monsoon(SCSSM) for the past 65 years.The summer monsoon onset(retreat) date is defined as the time when the mean zonal wind at 850 hPa shifts steadily from easterly(westerly) to westerly(easterly) and the pseudo-equivalent potential temperature at the same level remains steady at greater than 335 K(less than 335 K) in the South China Sea area[110-120°E(10-20°N)].The clockwise vortex of the equatorial Indian Ocean region,together with the cross-equatorial flow and the subtropical high,plays a decisive role in the burst of the SCSSM.The onset date of the SCSSM is closely related to its intensity.With late(early) onset of the summer monsoon,its intensity is relatively strong(weak),and the zonal wind undergoes an early(late) abrupt change in the upper troposphere.Climate warming significantly affects the onset and retreat dates of the SCSSM and its intensity.With climate warming,the number of early-onset(-retreat) years of the SCSSM is clearly greater(less),and the SCSSM is clearly weakened. 相似文献
10.
Summary The climatology and variability of summer convection and circulation over the tropical southwest Indian Ocean is investigated using satellite imagery, routine synoptic observations, outgoing longwave radiation (OLR) data, sea surface temperatures (SST) and areal averaged rainfall departures. OLR has a –0.90 correlation with rainfall departures and the OLR minimum (ITCZ) in January and February lies across the 10°S latitude, extending further south near Madagascar. The intensity of ITCZ convection is greatest in the longitudes 20–35°E over northern Zambia and is considerably reduced over the SW Indian Ocean. Spatial correlations are analyzed for standardized departures of OLR, rainfall and SST. The correlations change sign in a coherent fashion, creating a climatic dipole between southern Africa and the SW Indian Ocean. Interannual trends are examined through analysis of January–February zonal and meridional wind indices constructed from significantly correlated variables at Zimbabwe, Madagascar and Mauritius. Circulation variability is dominated by quasi-decadal cycles and a trend of inereasing westerly winds. Zonal wind shear alternates from easterly (barotropic) to westerly and together with SST appears to regulate the frequency and intensity of tropical cyclogenesis. Areally averaged rainfall departures exhibit 6.25 year cycles in NE Madagascar and 12.5 and 18.75 year cycles in SW Madagascar and Zimbabwe, respectively. Summer rainfall and meridional winds in NE Madagascar and Zimbabwe are out of phase and negatively correlated in most summers. The presence of synoptic weather systems is assessed using daily Hovmoller-type satellite imagery composites. Convective structure is dominated by transient waves in the 10°–20°S latitude band, with periods of 15–20 days common. The waves are more prominent in summers with increased easterly shear and contribute to fluctuations in rainfall over SE Africa.With 8 Figures 相似文献
11.
Multi-scale contributions are involved in the South China Sea (SCS) summer monsoon (SCSSM) onset process. The relative roles of intraseasonal oscillation and above-seasonal component in the year-to-year variation of the SCSSM onset are evaluated in this study. The 30-90-day and above-90-day components are major contributors to the year-to-year variation of the SCSSM onset, and the former contributes greater portion, while the 8-30-day component has little contribution to the onset. In the early onset cases, the 30-90-day westerly winds move and extend eastward from the tropical Indian Ocean (TIO) to the SCS monsoon region relatively earlier, and replace the easterly winds over the SCS with the cooperation of the 30-90-day cyclone moving southward from northern East Asia. The westerly anomalies of the above-90-day component in spring jointly contribute to the early SCSSM onset. In the late onset cases, the late eastward expansion of 30-90-day westerly wind over the TIO, accompanied by the late occurrence and weakening of the 30-90-day anticyclone over the SCS, and its late withdraw from the SCS, as well as the persistent easterly anomalies of above-90-day component, suppress the SCSSM onset. However, the SCSSM outbreaks in the obvious weakening stage of 30-90-day easterly anomalies. The easterlies-to-westerlies transition of the 30-90-day 850- hPa zonal wind over the SCS in spring is closely associated with sea surface temperature in the tropical western Pacific in preceding winter and spring, while the interannual variation of the above-90-day zonal wind in April-May is closely related to the decaying stage of the El Ni?o-Southern Oscillation events. 相似文献
12.
采用EOF分解和合成分析方法研究了1960-2003年山西夏季降水异常之北少(多)南多(少)型(第二类雨型)和山西省气温的变化异常.结果表明,两者具有较好的对应关系.分析了第二类异常雨型的时空分布,并给出相应的典型年份.EOF时间系数变化特征揭示了山西夏季降水第二类雨型有显著的年际振荡.利用合成分析,从500hPa位势高度场、纬向风、850hPa风场、700hPa水汽场和水汽输送场等物理量场研究了山西夏季第二类雨型的环流异常特征.结果表明,第二类雨型与弱的东亚夏季风相关联,北多南少和北少南多是弱夏季风的不同表现.山西省夏季降水北多南少年副高呈带状分布,位置偏北,强度较强;中高纬度地区异常波列呈大圆路径分布,在高纬度地区存在纬向排列的- -波列,同时在东亚大陆沿岸存在经向排列的- -波列.并且华北北部有西风异常,北支锋区偏北,由西南向东北水汽输送较强.北少南多年与之相反.海温场分析表明,第二类雨型与中北太平洋海温异常紧密相关. 相似文献
13.
利用奇异值分解 (SVD)方法分析和讨论了夏季 85 0hPa和 2 0 0hPa高低层纬向风距平差与我国夏季降水异常的关系 ,发现澳大利亚东北部高低层纬向风切变与长江中下游地区降水有较好的反相关 ,并定义了澳大利亚季风指数。 9个澳大利亚冬季风 (南半球 )指数低值年与 7个高值年我国夏季降水的平均差值图表明 ,显著的降水差异出现在长江中下游 ,低值年有利于长江中下游地区降水偏多 ;澳大利亚冬季风指数与夏季北半球 5 0 0hPa高度场的相关图在东亚至西太平洋的相关分布呈现出“ - -”结构 ,在我国长江以南的中低纬和贝加尔湖的高纬地区是负相关区 ,正相关在我国北方至日本的中纬地区。 相似文献
14.
利用1954-1998年NCAR/NCEP再分析资料及同期我国160个测站月降水资料,分析了热带地区100hPa东风与华北夏季降水之间的关系。结果表明:(1)从春季到夏季,东风强度与华北夏季降水具有显著而稳定的正相关关系。(2)弱东风年夏季,印度洋及印度次大陆表面温度均为正异常,然而赤道印度洋地区的正异常明显强于其南北两侧。海温异常的这一分布特征,一方面使得100hPa东风减弱;另一方面使得南亚地区海陆热力对比减弱,导致南亚夏季风偏弱,进而造成由该季风区向华北地区的水汽输送减少,华北地区干旱。 相似文献
15.
东亚高空纬向风的季节内振荡对登陆中国大陆热带气旋活动的影响 总被引:1,自引:2,他引:1
使用1979—2015年欧洲长期天气预报中心所提供的ERA-Interim再分析资料和中国气象局上海台风研究所整编的西北太平洋热带气旋(TC)最佳路径资料,分析了7—8月东亚高空纬向风的季节内振荡(ISO)信号特征及其与登陆中国大陆热带气旋(TC)的关系。结果表明:(1)200 hPa纬向风在副热带、中纬度地区季节内振荡显著,尤其是在纬向西风带中,有两个南北分布的大值中心,方差贡献均超过50%。(2)基于东亚高空纬向风的ISO和EOF典型空间模定义的西风指数(EAWI),可以用来描述东亚高空纬向西风在ISO尺度上的经向移动。(3)在西风指数的ISO负位相期间,登陆中国东南沿岸22 °N以北的TC增多;反之减少。在西风急流出口南侧的副热带区域,200 hPa ISO纬向风向北移动,使纬向西风位置偏北,出现东风异常,从而使西风减弱;TC引导气流为向西的异常,有利于TC登陆中国大陆偏北沿岸;同时有异常的ISO纬向异常东风切变,有利于TC登陆过程的维持。(4)在西风指数的ISO负位相期间,在对流层高层西风急流出口区向南输送的天气尺度的E矢量,在TC登陆地区,出现异常扰动涡度通量的辐合,引起了该区域的西风减弱。 相似文献
16.
运用2001年和2002年7个热带气旋 (TC) 登陆华南前后的38个日降水量、NCEP/NCAR再分析资料以及卫星云图, 经普查和分析将TC造成的降水区划分为纬向型、经向型、NE—SW向型3种; 对各型高、中、低层中的主要气象因子作了详细分析, 如高层流场、中层副热带高压、低层急流和切变线或辐合线、整层水汽通量散度以及季风云涌等, 在此基础上归纳概括出了这些降水型各自前24 h的大尺度环境场特征概略模型图, 并对其强降水形成机理尽可能地给出了解释, 为TC登陆前后的超短期降水预报提供某种参考方法。 相似文献
17.
Stratospheric zonal wind and temperature in relation to summer monsoon rainfall over India 总被引:1,自引:0,他引:1
Summary The interannual variability of the Indian summer monsoon (June–September) rainfall is examined in relation to the stratospheric
zonal wind and temperature fluctuations at three stations, widely spaced apart. The data analyzed are for Balboa, Ascension
and Singapore, equatorial stations using recent period (1964–1994) data, at each of the 10, 30 and 50 hPa levels. The 10 hPa
zonal wind for Balboa and Ascension during January and the 30 hPa zonal wind for Balboa during April are found to be positively
correlated with the subsequent Indian summer monsoon rainfall, whereas the temperature at 10 hPa for Ascension during May
is negatively correlated with Indian summer monsoon rainfall. The relationship with stratospheric temperatures appears to
be the best, and is found to be stable over the period of analysis.
Stratospheric temperature is also significantly correlated with the summer monsoon rainfall over a large and coherent region,
in the north-west of India. Thus, the 10 hPa temperature for Ascension in May appears to be useful for forecasting summer
monsoon rainfall for not only the whole of India, but also for a smaller region lying to the north-west of India.
Received July 30, 1999 Revised March 17, 2000 相似文献
18.
亚澳季风异常与ENSO准四年变化的联系分析 总被引:2,自引:0,他引:2
分析了赤道地区纬向风的年际变化特征,以及亚澳季风与ENSO在各个位相的联系。结果表明:赤道纬向风变化与中东太平洋海温变化在准四年周期上是强烈耦合的;在El Eino期间东亚冬季风弱,夏季风强,而南亚夏季风弱,反之,在La Nina期间东亚冬季风强,夏季风弱,而南亚夏季风强;东亚地区的异常北风有利于西太平洋西风异常爆发,使得东太平洋海温升高,但只有随后在中东太平洋出现持续性西风异常,El Nino才能发展,其中来自太平洋中部的异常北风(并不是来自东亚大陆地区)和南太平洋中部的异常南风的辐合对中东太平洋出现持续性西风异常起重要的作用,尤其是澳大利亚东北部的季风异常的影响更为显。 相似文献
19.
利用NCEP逐日再分析资料,计算和分析了1949~2009年的南海季风爆发时间,并分析讨论了南海季风爆发偏早年和偏晚年大气环流的差异。结果表明:1)南海季风的爆发伴随着该地区降水的显著增加,且爆发时间在1958~1997年间呈偏早趋势。2)在南海季风爆发早年相对于晚年,中高层纬向风在青藏高原和西南太平洋西风异常偏强、孟加拉湾和南海有东风异常偏弱。3)在低层,孟加拉湾、南海和东海西风异常偏强、西南太平洋东风异常偏弱;而青藏高原北部塔里木盆地北风异常偏弱、中国中东部、南海和孟加拉湾南风异常偏弱、东海南风异常偏强。亚欧大陆、印度洋、南海和西南太平洋的大气环流异常与南海地区降水关系密切。 相似文献
20.
Tropical cyclone potential hazard in Southeast China and its linkage with the East Asian westerly jet 总被引:1,自引:0,他引:1
A new synthesized index for estimating the hazard of both accumulated strong winds and heavy rainfall from a tropical cyclone (TC) is presented and applied to represent TC potential hazard over Southeast China. Its relationship with the East Asian westerly jet in the upper troposphere is also investigated. The results show that the new TC potential hazard index (PHI) is good at reflecting individual TC hazard and has significantly higher correlation with economic losses. Seasonal variation of TC-PHI shows that the largest TC-PHI on average occurs in July-August, the months when most TCs make landfall over mainland China. The spatial distribution of PHI at site shows that high PHI associated with major landfall TCs occurs along the southeast coast of China. An East Asian westerly jet index (EAWJI), which represents the meridional migration of the westerly jet, is defined based on two regions where significant correlations exist between TC landfall frequency and zonal wind at 200 hPa. Further analyses show that an anomalous easterly steering flow occurred above the tracks of TCs, and favored TCs making landfall along the southeast coast of China, leading to an increase in the landfall TC when the EAWJ was located north of its average latitude. Meanwhile, anomalous easterly wind shear and positive anomaly in low-level relative vorticity along TCs landfall-track favored TC development. In addition, anomalous water vapor transport from westerly wind in the South China Sea resulted in more condensational heating and an enhanced monsoon trough, leading to the maintenance of TC intensity for a longer time. All of these environmental factors increase the TC potential hazard in Southeast China. Furthermore, the EAWJ may affect tropical circulation by exciting meridional propagation of transient eddies. During a low EAWJI phase in July-August, anomalous transient eddy vorticity flux at 200 hPa propagates southward over the exit region of the EAWJ, resulting in eddy vorticity flux convergence and the weakening in the zonal westerly flow to the south of the EAWJ exit region, producing a favorable upper-level circulation for a TC making landfall. 相似文献