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1.
中国东部—西太平洋副热带季风和降水的气候特征及成因分析 总被引:13,自引:2,他引:11
利用1981—2000年候平均NCEP/NCAR再分析资料和CMAP全球降水资料,分析了从中国东部大陆到西太平洋副热带地区季风和降水季节变化的特征及其与热带季风降水的关系,探讨了季风建立和加强的原因。夏季东亚—西太平洋盛行的西南风开始于江南和西太平洋副热带的春初,并向北扩展到中纬度,热带西南风范围向北扩展的迹象不明显。从冬到夏,中国西部和西太平洋副热带的表面加热季节变化可以使副热带对流层向西的温度梯度反转比热带早,使西南季风在副热带最早开始;从大气环流看,青藏高原东侧低压槽的加强和向东延伸,以及西太平洋副热带高压的加强和向西移动,都影响着副热带西南季风的开始和发展;初夏江南的南风向北扩展与副热带高压向北移动有关,随着高原东侧低压槽向南延伸,槽前的偏南风范围向南扩展。随着副热带季风建立和向北扩展,其最大风速中心前方的低层空气质量辐合和水汽辐合以及上升运动也加强和向北移动,导致降水加强和雨带向北移动。热带季风雨季开始晚,主要维持在热带而没有明显进入副热带,江淮梅雨不是由热带季风雨带直接向北移动而致,而是由春季江南雨带北移而致。在热带季风爆发前,副热带季风区水汽输送主要来自中南半岛北部和中国华南沿海,而在热带季风爆发后,水汽输送来自孟加拉湾和热带西太平洋。 相似文献
2.
Characteristics of Subtropical Monsoon and Rainfall over Eastern China and Western North Pacific 
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下载免费PDF全文 Using the NCAR/NCEP (National Center for Atmospheric Research/National Centers for Environmental
Prediction) reanalysis and the NOAA Climate Prediction Center's merged analysis of precipitation (CMAP)during 1981-2000, we investigated the seasonal evolution of the southwesterly wind and associated precipitation over the eastern China-subtropical western North Pacific area and its relationship with the tropical monsoon and rainfall, and analyzed the reasons responsible for the onset and development of the wind. It was found that the persistent southwesterly wind appears over southern China and the subtropical western Pacific the earliest in early spring, and then expands southwards to the tropics and advances northward to the midlatitudes. From winter to summer, the seasonal variation of surface heating over western China and the subtropical western Pacific may result in an earlier reversal of the westward tropospheric temperature gradient over the subtropics relative to the tropics, which may contribute to the earliest beginning of the subtropical southwesterly wind. Additionally, the strengthening and eastward expanding of the trough near the
eastern Tibetan Plateau as well as the strengthening and westward moving of the western Pacific subtropical high also exert positive influences on the beginning and development of the subtropical southwesterly wind.In early summer,the northward expansion of the southwesterly wind over southern China is associated with a northward shift of the subtropical high, while the southward stretch of the southwesterly wind is associated with a southward stretch of the trough in the eastern side of the plateau. With the beginning and northward expansion of the subtropical southwesterly wind (namely southwest monsoon), convergences of the low-level air and water vapor and associated upward motion in front of the strongest southwesterly wind core also strengthen and move northward, leading to an increase in rainfall intensity and a northward shift of the rain belt. Accordingly, the subtropical rainy season occurs the earliest over southern China in spring, moves northward to the Yangtze-Huaihe River valley in early summer, and arrives in North China in mid summer.Compared with the subtropical rainy season, the tropical rainy season begins later and stays mainly over the tropics, not pronouncedly moving into the subtropics. Clearly, the Meiyu rainfall over the Yangtze-Huaihe River valley in early summer results from a northward shift of the spring rain belt over southern China,instead of a northward shift of the tropical monsoon rain belt. Before the onset of the tropical monsoon,water vapor over the subtropical monsoon region comes mainly from the coasts of the northern Indo-China Peninsula and southern China. After the onset, one branch of the water vapor flow comes from the Bay of Bengal, entering into eastern China and the subtropical western Pacific via southwestern China and the South China Sea, and another branch comes from the tropical western North Pacific, moving northwestward along the west edge of the western Pacific subtropical high and entering into the subtropics. 相似文献
3.
2006年北半球大气环流及对中国气候异常的影响 总被引:5,自引:0,他引:5
2006年,赤道中东太平洋经历了一次从La Nina状态到El-Nino事件的过程。500hPa高度场上,欧亚中高纬度地区前冬为经向型环流,后冬亚洲地区盛行纬向环流;夏、秋季,亚洲高纬度地区为经向型环流而中纬度为纬向环流,这种环流形势不利于冷空气南下,导致我国2006年的夏、秋季变得异常暖。2006年西太平洋副热带高压面积偏大、强度偏强且西伸脊点异常偏西。夏季没有出现持续性的较强的阻塞形势,从而使长江中下游地区降水较常年同期偏少,梅雨较弱。东亚夏季风异常偏强。2005/2006年冬季,青藏高原温度异常偏高,各季的高度场也较常年同期偏高,这有利于副高的加强西伸,而7-8月、10月太平洋暖池区对流活动强盛,为热带气旋的生成发展提供了有利的动力条件,并在副高的引导下多为西行路径。 相似文献
4.
Based on the analysis of NCEP height, wind and OLR data, the influence of spring equatorial
eastern Pacific SSTA on the seasonal change from spring to summer of eastern Asian circulation has been
investigated. Results show that related to the warm (cold) spring SSTA in the equatorial eastern Pacific, the
anomalous anticyclone (cyclone) circulation emerges around the South China Sea and the Philippines, the strong
(weak) west Pacific subtropical high locates to the west (east) of its normal position, which induces to the late
(early) onset of the South China Sea monsoon. The numerical simulations have also shown that the remarkable
influence of spring SSTA in the equatorial eastern Pacific on the spring seasonal change of eastern Asian
circulation will last till summer. 相似文献
5.
EFFECTS OF THE ATMOSPHERIC COLD SOURCE OVER THE TIBETAN PLATEAU ON THE QUASI 4-YEAR OSCILLATION OF OCEAN-ATMOSPHERIC-LAND INTERACTION 总被引:1,自引:0,他引:1
Using correlation analyses, composite analyses, and singular value decomposition, the relationship between the atmospheric cold source over the eastern Tibetan Plateau and atmospheric/ocean circulation is discussed. In winter, the anomaly of the strong (weak) atmospheric cold source over the eastern plateau causes low-level anomalous north (south) winds to appear in eastern China and low-level anomaly zonal west (east) winds to prevail in the equatorial Pacific from spring to autumn. This contributes to the anomalous warm (cold) sea surface temperature the following autumn and winter. In addition, the anomalous variation of sea surface temperature over the equatorial middle and eastern Pacific in winter can influence the snow depth and intensity of the cold source over the plateau in the following winter due to variation of the summer west Pacific subtropical high. 相似文献
6.
2006年杭嘉湖平原夏秋天气异常分析 总被引:1,自引:0,他引:1
2006年杭嘉湖平原出现夏季特长、秋季极短,梅雨量极少、高温天数多、夏旱连秋旱的气候异常现象,对大气环流进行分析发现,西太平洋副高持续偏强偏西,北半球极涡偏弱,冷空气活动偏北,亚洲地区盛行纬向环流.区域气候的异常与大气环流的季节转换异常有关,并且大气环流的异常可以追溯到其前期环流的异常.2006年前冬和春季中高纬度较强的经向环流和持续偏强的副热带高压使得该年夏季副高继续偏强,并且春季的这一环流异常现象,导致秋季大气环流向冬季过渡较快.对涡动高度的分析表明,5月平流层正中心的异常两移、6~7月平流层持续分裂出两个正中心,以及9月正中心的异常增强,预示和促进了夏季低层大气环流的异常发展,从而夏季偏长、夏秋季节转换推迟;11月冷低压的异常增强南压和暖高压的突然减弱,使秋冬季节转换较快,从而秋季极短. 相似文献
7.
根据全球气溶胶气候模式GEM-AQ/EC的1995~2004年模拟,分析了青藏高原大气黑碳气溶胶的来源、传输及沉降季节特征。研究表明:青藏高原黑碳气溶胶主要来自自由对流层和大气边界层的输送。相对于自由对流层的黑碳输送,紧邻青藏高原的南亚、东亚以及东南亚大气边界层的输送更有效,它形成了青藏高原由北向南、自西往东黑碳气溶胶浓度和沉降明显递增的基本分布形态。横跨欧亚大陆自由对流层的黑碳气溶胶由西向东向青藏高原的输送全年不变,夏季输送路径最北但强度最弱,冬季路径最南而强度最强。大气边界层黑碳气溶胶的输送受控于亚洲季风环流变化,来自南亚的黑碳气溶胶在春季越过孟加拉湾传输进入高原东南部,夏季则可翻越喜马拉雅山抵达青藏高原南部腹地;同时我国中部排放的黑碳气溶胶也在东亚夏季风向北扩展中驱动它从东向西往青藏高原东北部传输。从秋季到冬季,随着夏季风撤退,南亚黑碳源区向青藏高原传输衰退,东亚冬季风的反气旋性环流的南侧及西南侧的偏东风携带秋季我国东南部源区和冬季东南亚源区黑碳气溶胶向青藏高原东南部传输。受青藏高原明显的暖湿季和干冷季气候影响,干湿沉降分别主导了青藏高原冬季和夏季黑碳沉降,夏季青藏高原黑碳气溶胶沉降总量大多超过8~10 kg·km-2,在高原东北部的最高值超过40 kg·km-2。冬季青藏高原黑碳气溶胶沉降量最低,大部地区黑碳沉降低于5 kg·km-2。青藏高原黑碳沉降的冬夏季节相差约为2~8倍。 相似文献
8.
春季赤道东太平洋海温异常对西太平洋副高的影响 总被引:13,自引:3,他引:10
首先给出西太平洋副高脊线、面积和西伸指数的定义 ,在此基础上讨论赤道东太平洋海温异常与西太平洋副高的年际变化关系 ,并进一步分析了春季赤道东太平洋海温异常对西太平洋副高季节变化的影响。结果表明 ,春季赤道东太平洋海温异常与夏季副高位置和强度的年际变化及季节变化都有密切关系。从春季到夏季 ,春季海温偏暖年副高偏南、偏强、偏西 ;偏冷年副高偏北、偏弱、偏东 ,冷年 6月副高北跳较暖年显著 ,进入秋季后南撤更为迅速 相似文献
9.
东亚副热带急流的空间结构及其与中国冬季气温的关系 总被引:5,自引:1,他引:4
本文利用1950~2012 年NCEP/NCAR 逐月再分析风场资料和中国542 个台站逐日观测资料研究东亚副热带急流(EAJ)的空间结构及其与中国冬季气温的关系。结果表明,东亚副热带急流在空间呈不规则管状结构,冬季急流体积最大,垂直厚度范围自500 hPa 至100 hPa;夏季急流体积最小,仅存在于200 hPa 附近。急流管在秋、冬、春季略呈西南—东北走向,在夏季呈西—东走向。不同高度上的最大风速轴线在南北方向的移动不尽一致,春、秋季低层风速轴比高层偏北。东亚急流管不同区域下方的垂直运动及其年变化存在差异。冬季东亚副热带急流强度与同期中国气温关系密切,特别是高原上空的急流越强时,中国大部分地区冬季气温偏低。 相似文献
10.
Cai Yao Weihong Qian Song Yang Zhengmin Lin 《Meteorology and Atmospheric Physics》2010,106(1-2):57-73
The variations of both total and extreme precipitations over Asia are characterized by large regional features and seasonality. Extreme precipitation mainly occurs in summer and then in autumn over South Asia but it is a prominent phenomenon in all seasons over Southeast Asia. It explains above 40% of the total precipitation in winter over India, while the ratio of extreme precipitation to total precipitation is 30% or smaller in all seasons over southern-central China. Over Southeast Asia, the largest ratio appears in winter. The extreme precipitation over Southeast Asia (EPSEA) exhibits significant positive trends in all seasons except autumn. The long-term increase in summer EPSEA is associated with significant surface warming over extratropical Asia and the Indo-Pacific oceans and linked to a large-scale anomalous cyclonic pattern over Southeast Asia. An increase in de-trended summer EPSEA is associated with less significant surface warming. However, it is still clearly linked to an anomalous cyclonic pattern over Southeast Asia, contributed by intensifications of monsoon flow from the west, trade wind from the east, and cross-equatorial flow over Indonesia. The antecedent features of increased summer EPSEA include an overall warming over the tropical–subtropical northern hemisphere and an anomalous cyclonic pattern over Southeast Asia in winter and spring. When the large-scale Asian monsoon (measured by the Webster-Yang monsoon index) or the South Asian monsoon is strong, summer extreme precipitation mainly increases over tropical Asia. When monsoon is strong over Southeast Asia or East Asia, extreme precipitation increases over Southeast Asia and decreases over East Asia. A strong summer monsoon over Southeast Asia or East Asia is also followed by decreased autumn extreme precipitation over Southeast Asia. 相似文献
11.
1998年大气环流异常及其对中国气候异常的影响 总被引:57,自引:8,他引:49
1998年受ENSO事件和青藏高原冬春季积雪多等因素的影响,北半球大气环流的主要特征是:500hPa西太平洋副高强大,夏季副高脊线位置偏南;冬、夏季风均较弱;赤道辐合带偏弱,在西太平洋生成和登陆影响我 斩台风和热带风暴异常偏少;夏季亚洲中高纬度经向环流发展,其它季节则以纬向环流为主;环流异常是影响1998年中国气候极其异常的主要原因。 相似文献
12.
受高原地形影响, 低层西风气流在高原西侧分支, 从南北两侧绕流, 在高原东侧汇合, 并在南(北)侧形成定常的正(负)涡度带。本文利用NCEP/NCAR提供的1951-2004年再分析资料, 发现这两个涡度带在700 hPa上最明显, 常年存在一正一负两个对称的涡旋(下称“涡旋对”), 且冬, 春季较强。根据各月涡旋对的位置及强度, 本文定义冬, 春季绕流指数为正\, 负涡旋对平均涡度之差, 定量地表征高原绕流作用的强弱, 绕流指数大则高原绕流作用强。结果表明, 1951-2004年中2/3的年份高原绕流作用春季强于冬季, 高原绕流作用不仅是高原大地形的动力作用造成的, 而且受到热力作用的影响。冬季绕流指数以年代际变化为主, 近50年冬季高原绕流作用有显著的增强趋势; 春季绕流指数年代际和年际变化均不明显。冬、 春季, 强高原绕流作用均有利于中高纬冷空气向我国北方输送, 使东北及新疆北部地区气温偏低。春季强高原绕流作用还有利于高原东南侧的暖湿气流向华南及江南地区输送, 使西南、 华南部分地区气温偏高; 偏南暖湿气流和来自中高纬的偏北冷干气流在31°N附近辐合, 有利于江淮地区降水。无论冬\, 春季, 亚洲中纬度西风强度是影响高原绕流作用的重要因子。 相似文献
13.
ERA40再分析资料揭示的北半球和东亚地区温带气旋生成频率变化 总被引:6,自引:0,他引:6
本文利用欧洲中心再分析数据ERA40的6小时间隔海平面气压场和一种改进的客观判定和追踪方法研究19582001年北半球和东亚地区温带气旋生成频率的气候态、年代际变化及可能原因。结果表明:(1)北半球温带气旋的源地主要位于北美东部(落基山下游地区)、西北大西洋地区、格陵兰至欧洲北部地区、蒙古地区和日本至西北太平洋地区。大洋的西岸和陡峭地形的背风坡有利于大气斜压性的增强和正涡度的发展,从而有利于地面气旋的形成。(2)年、冬季和春季30°~60°N气旋生成数目呈现减少的变化趋势,60°~90°N地区的气旋生成数呈增加的变化趋势。这在一定程度上支持了北半球风暴路径北移的观点。60°N以南和以北的温带气旋数目同北极涛动指数(AO)分别呈现负相关和正相关,这种相关性在年、春季和秋季最为显著。(3)1 958—2001年东亚地区的年气旋数目呈现明显的年代际变化。20世纪60年代至80年代中期40°~60°N、80°~140°E地区气旋数目呈增加趋势,而80年代中期之后温带气旋数目则锐减,主要原因是80年代以后该地区大气斜压性减弱,更高纬度地区的大气斜压性增强,从而导致了气旋源地的北移。在较低纬带的20°~40°N、110°~160°E地区气旋数目线性增加,这主要是由于位于40°~55°N的北太平洋风暴轴有向低纬度偏移的变化趋势造成的。 相似文献
14.
2000年受La Nina结束后冷水事件的影响,北半球大气环充的要主特征表现为:500hPa东亚中纬度呈经,纬向环流交替分布,西太平洋副热带高压偏弱,偏北,偏东,热带对流活动冬季偏强,夏季偏弱,赤道辐合带偏弱,在上述大气环流的影响下,台风偏少,夏季主要多雨带位于黄河与长江之间,黄河以北地区干旱严重。 相似文献
15.
1997年北半球大气环流特征及其影响 总被引:1,自引:0,他引:1
1997年北半球主要环流特征为:500hPa西太平洋副热带高压盛夏由弱转强、西伸明显、脊线位置偏北;亚洲中纬度经、纬向环流交替出现,纬向环流盛行,春、秋季经向环流加强,冬、夏季冷空气异常偏弱;盛夏南海季风增强,印度季风偏弱;赤道辐合带偏弱。北半球100hPa中低纬度位势高度持续偏高,南亚高压东扩明显;热带海洋出现异常,一次新的厄尔尼诺事件发生,强度大、发展快。在ENSO和大气环流的共同影响下我国天 相似文献
16.
1999年北半球大气环流特征及其影响 总被引:3,自引:0,他引:3
1999年北半球主要环流特征为:500hpa西太平洋副热带高压较常所明显偏弱,春、夏季副高位置异常偏东;东亚地区夏季500hpa位势高度距平场上表现为北高南低,大陆高压较强。亚洲中纬度经、纬向环流交替出现,阶段性明显;冬季冷空气异常偏弱,东亚夏季风加强。冬、春季热带对流活动强盛,入夏以后迅速减弱。在La-nina和大气 环流的共同影响下我国天气气候发生了明显异常。 相似文献
17.
<p>PARTITION OF SEASON BASED ON MULTIELEMENTS AND THE DECADAL CHANGE OF SEASON DURATION IN CHINA</p>
<p>Using the multielements similarity measurement method and 1950–C2017 NCEP/NCAR gridded daily reanalysis datasets, we analyzed season duration in China during 1950–C2016, and we defined the element with maximum absolute sensitivity as the key impact element at each point using the sensitivity analysis method. The decadal change of season duration and its key impact element before and after 1980 were studied. The results indicated obvious meridional and zonal differences in the distribution of season duration for the 67-year average, and that the key impact element has the same distribution characteristics as season duration. In addition, complementary relationships were found between the durations of spring and summer, autumn and winter, and the cold and warm seasons. Of those, the complementary relationship between the durations of spring and summer was strongest and the regions of complementarity were numerous. The complementary regions of autumn and winter durations were found mainly in western China. In the cold and warm seasons, the complementary regions were widespread and the complementary relationship was generally weak. Comparison of the periods before and after 1980 revealed an east–Cwest difference in the interdecadal variation of season duration. Interdecadal variation in spring and summer was found concentrated in northern and western regions, while that in autumn and winter was concentrated in the western region. Areas of significant interdecadal variation of the key elements were found concentrated in northern and western regions, corresponding well with the areas of significant interdecadal variation of season duration.</p> 相似文献
18.
水汽输送与江南南部初夏雨季及降水变化的联系 总被引:6,自引:1,他引:6
基于1961—2010年美国国家环境预报中心/大气研究中心(NCEP/NCAR)的逐日再分析格点资料,分析了初夏水汽输送的分布和演变过程及其与中国江南南部初夏雨季的关系。结果显示,初夏水汽输送总体上随夏季风前沿自南向北加强,有3次水汽通量突然增大的涌先后从中国南海北传到25°N及其以南、25°—30°N、30°N及其以北地区,水汽涌和相应峰的发生时间分别对应华南前汛期、江南南部初夏雨季、长江流域梅雨的开始和结束时间。江南南部在初夏雨季处在水汽通量高值区的北缘、水汽辐合区内。青藏高原南侧水汽辐散区是影响江南南部初夏雨季的直接水汽源,澳大利亚北部到印度洋和阿拉伯海南部地区的大面积水汽辐散区则是间接水汽源。经向水汽输送演变对雨季起(讫)具有标志性意义,纬向水汽输送也不容忽视。雨季开始(结束)时江南南部地区的南界(北界)中低层水汽流入(流出)显著增大,但北界(南界)水汽通量并未同步发生显著变化;雨季期间的纬向水汽输送明显增强,水汽通量大于经向水汽输送。雨季强、弱具有年代际变化,且与纬向水汽流入的相关比经向水汽流入的相关更显著。影响江南南部初夏雨季的水汽输送路径主要有两条,北支是从孟加拉湾北部经缅甸和云南、贵州的水汽输送,南支是经孟加拉湾、中南半岛、中国南海与西太平洋副热带高压西侧水汽汇合的水汽输送。强雨季年孟加拉湾北部的东北向水汽输送和中国南海的北向水汽输送都增强,弱雨季年则相反。孟加拉湾、中国南海南部和西太平洋暖池区是显著的水汽辐合区,是江南南部初夏雨季的水汽输送通道而不是水汽源,水汽辐合越弱(强)越有利于(不利于)江南南部初夏雨季的降水,其影响机制可能在于通道上的对流活动对江南南部初夏雨季水汽输送具有拦截作用。 相似文献
19.
Thomas J. Bracegirdle 《Climate Dynamics》2011,37(11-12):2323-2333
The semi-annual oscillation (SAO) in sea-level pressure at high southern latitudes is the consequence of a twice-yearly contraction (and strengthening) and expansion (and weakening) of the storm track between 50 and 65°S, with the contracted phases in spring and autumn. In this study the extent to which inter-annual variability of the SAO is correlated with inter-annual variability in mid- to lower-stratospheric circulation at 60°S was determined using NCEP/NCAR Reanalysis 1 data for the period 1979?C2009. The second harmonic of the annual cycle of an SAO index was used to assess SAO amplitude and phase (the date of the first peak of the second harmonic). Zonal mean zonal wind at 60°S was used as an index for atmospheric circulation. The results show that year-to-year variability in the SAO amplitude is significantly correlated with mid-stratospheric (10?hPa) circulation variability in late summer/early autumn (February?CMarch) and late winter/early spring (August?CSeptember). However, variability in the SAO phase is significantly correlated with mid-stratospheric circulation variability in spring (September?CNovember). These maxima in significant correlations at 10?hPa propagate down to the surface in approximately one month. The characteristics of upward planetary wave propagation alone do not explain the late summer/early autumn and spring maxima in correlations. Evidence is shown that internal reflection of stationary wave-number 1 is important for explaining the strong correlations in late summer/early autumn, but that large variability during polar vortex break-up dominates the spring correlations. The results may be important for understanding seasonal differences in how stratospheric ozone depletion influences tropospheric circulation. 相似文献
20.
1996年北半球主要环流特征是:500hPa西太平洋副高偏弱,脊线位置初夏偏北,盛夏西端持续偏南;亚洲西风带后冬至初春经向环流明显发展,7月亚洲中纬度地区常有阻塞形势维持,500hPa青藏高原位势高度偏高,夏季南支印缅槽较弱。 相似文献