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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
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The correlation analysis has been used to study the relationship between spring soil moisture over China and East Asian summer monsoon (EASM). It is shown that EASM has a strong positive correlation with spring soil moisture over southwest China and the Great Bend region of the Yellow River. A standard soil moisture index (SMI) has been defined using the observed soil moisture of the two regions. The results show that SMI has a strong correlation with EASM. The years of strong (weak) SMI are associated with stronger (weaker) summer monsoon circulation. In the years of strong SMI, the west Pacific subtropical high is much northward in position and weaker in intensity; the westerlies zone is also more to the north. All of these make EASM circulation move northward and cause the rainfall belt to relocate to North China and Northeast China. SMI can reflect the variation of the summer rainfall anomaly over eastern China. In the years of strong SMI, the rainfall belt is mainly located over the northem part of China.However, during the weak years, the summer rainfall belt is largely located over the mid- and lower- reaches of the Yangtze River. Additionally, the SMI has obvious oscillations of quasi 4-6 years and quasi 2 years. Moreover, negative SMI predicts EASM better than positive SMI. 相似文献
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2005年6月华南致洪暴雨过程中FY-2C卫星TBB场分析 总被引:8,自引:1,他引:8
利用水平分辨率1°×1°经纬度的FY-2C卫星相当黑体亮度温度(TBB)网格资料,探讨了2005年6月18—22日华南致洪暴雨过程中TBB的平均场分布特征及其演变特点,以求得华南地区对流云带(团)生消与暴雨的内在联系。结果表明:TBB场能较直观地反映暴雨过程中积云对流活动、降水的分布和强度特征,TBB低值带与华南地区强暴雨落区有很好的对应关系;强盛的西南季风对华南地区强对流云系的生成、发展和维持起了主导作用;对流云带(团)以缓慢东移为主,随着云带(团)TBB值降低,降水强度逐渐加大;TBB有明显的日变化,同时伴随着雨强的日变化。 相似文献
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1998 SCSMEX期间亚洲30-60天低频振荡特征的分析 总被引:34,自引:0,他引:34
对1998年 5-8月南海季风试验(SCSMEX)期间东亚地区 850 hPa中低纬环流指数、东亚季风指数和长江中下游降水进行了Morlet 小波分析,结果表明在此期间这些要素均有明显的30-60天周期低频振荡。在此基础上对 5-8月每隔 5天的 850 hPa低频流场进行分析,结果表明:(1)100°-150°E间东亚从中国东中部大陆经南海和西太平洋的南北半球中明显的存在一个以30-60天低频荡为特征的东亚季风低频环流系统,东亚季风活动主要受东亚季风系统中低频活动影响;(2)5月第5候南海热带季风爆发、6月中旬长江中下游人梅及产生大暴雨以及7月中旬以后的该地区大暴雨均与低频气旋带在该地区活动有关,而8月长江上游大暴雨则与低频反气旋伸人到大陆有关;(3)SCSMEX期间东亚低频振荡系统的源地有二个,即南海赤道和北半球中太平洋中高纬。南海低频系统向北传播,而中高纬低频系统自东北向西南传播为主。长江中下游6、7月二次大暴雨均与上述二个低频气旋系统自热带向北和中高纬向西南传播并于长江中下游汇合有关;(4)5-8月间东亚季风系统中有二次低频气旋带和二次低频反气旋带活动,这些低频环流系统的活动与印度季风低频环流系统活动并无明� 相似文献
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The wavelet analysis is performed of the mid- and low-latitude circulation index at 850 hPa over East Asia, the East Asian
monsoon index and the precipitation over the middle and lower reaches of the Yangtze River during 1998 South China Sea Monsoon
Experiment (SCSMEX) from May to August. Analysis shows that distinct 30–60 day low-frequency oscillation (LFO) exists in all
of the above elements during the exper-iment period. Analysis of low-frequency wind field at 850 hPa from May to August with
5 days interval is performed in this paper. Analysis results reveal that: (1) A low-frequency monsoon circulation system over
East Asia, characterized by distinct 30–60 day low-frequency oscillation, exists over 100°-150°E of East Asian area from the
middle and eastern parts of China continent and the South China Sea to the western Pacific in both the Northern and Southern
Hemisphere. The activity of East Asian monsoon is mainly af-fected by the low-frequency systems in it; (2) All of the tropical
monsoon onset over the South China Sea in the fifth pentad of May, the beginning of the Meiyu period and heavy rainfall over
the middle and lower reaches of the Yangtze River in mid-June and the heavy rainfall after mid-July are related to the activity
of low-frequency cyclone belt over the region, whereas the torrential rainfall over the upper reaches of the Yangtze River
in August is associated with the westward propagation of low-frequency anticyclone into the mainland; (3) There are two sources
of low-frequency oscillation system over East Asia during SCSMEX. i.e. the equatorial South China Sea (SCS) and mid-high latitudes
of the middle Pacific in the Northern Hemisphere. The low-frequency system over SCS propagates northward while that in mid-high
latitudes mainly propagates from northeast to southwest. Both of the heavy rainfall over the middle and lower reaches of the
Yangtze River in June and July are associated with the northward propagation of the above-mentioned SCS low-frequency systems
from the tropical region and the southwestward propagation from mid-high latitudes respectively and their convergence in the
middle and lower reaches of the Yangtze River; (4) There are two activities of low-frequency cyclone and anticyclone belt
each in the East Asian monsoon system during May to August. However the activity of these low-frequency circulation systems
is not clearly relevant to the low-frequency circulation system in the Indian monsoon system. This means that the low-frequency
circulation systems in Indian monsoon and East Asian monsoon are independent of each other. The concept previously put forward
by Chinese scholars that the East Asian monsoon circulation sys-tem (EAMCS) is relatively independent monsoon circulation
system is testified once more in the summer 1998.
This work was supported by the key project A of the State Ministry of Science and Technology “South China Sea Monsoon Experiment”
and the fruit of it. 相似文献
7.
ON THE PROCESS OF SUMMER MONSOON ONSET OVER EAST ASIA 总被引:6,自引:0,他引:6
Using daily observational rainfall data covered 194 stations of China from 1961 to 1995 andNCEP model analyzed pentad precipitation data of global grid point from 1979 to 1997,thedistribution of onset date of rainy season over Asian area from spring to summer is studied in thispaper.The analyzed results show that there exist two stages of rainy season onset over East Asianregion from spring to summer rainy season onset accompanying subtropical monsoon and tropicalmonsoon respectively.The former rain belt is mainly formed by the convergence of cold air and therecurred southwesterly flow from western part of subtropical high and westerly flow from the so-called western trough of subtropical region occurring during winter to spring over South Asia.Thelatter is formed in the process of subtropical monsoon rain belt over inshore regions of South ChinaSea originally coming from south of Changjiang (Yangtze) River Basin advancing with northwardshift of subtropical high after the onset of tropical monsoon over South China Sea.The pre-floodrainy season over South China region then came into mature period and the second peak of rainfallappeared.Meiyu,the rainy season over Changjiang-Huaihe River Basin and North China thenformed consequently.The process of summer tropical monsoon onset over South China Sea in 1998is also discussed in this paper.It indicated that the monsoon during summer tropical monsoononset over South China Sea is the result of the westerly flow over middle part of South China Sea,which is from the new generated cyclone formed in north subtropical high entering into SouthChina Sea,converged with the tropical southwesterly flow recurred by the intensified cross-equatorial flow. 相似文献
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Using daily observational rainfall data covered 194 stations of China from 1961 to 1995 and NCEP model analyzed pentad precipitation data of global grid point from 1979 to 1997,the distribution of onset date of rainy season over Asian area from spring to summer is studied in this paper.The analyzed results show that there exist two stages of rainy season onset over East Asian region from spring to summer rainy season onset accompanying subtropical monsoon and tropical monsoon respectively.The former rain belt is mainly formed by the convergence of cold air and the recurred southwesterly flow from western part of subtropical high and westerly flow from the so-called western trough of subtropical region occurring during winter to spring over South Asia.The latter is formed in the process of subtropical monsoon rain belt over inshore regions of South China Sea originally coming from south of Changjiang (Yangtze) River Basin advancing with northward shift of subtropical high after the onset of tropical monsoon over South China Sea.The pre-flood rainy season over South China region then came into mature period and the second peak of rainfall appeared.Meiyu,the rainy season over Changjiang-Huaihe River Basin and North China then formed consequently.The process of summer tropical monsoon onset over South China Sea in 1998 is also discussed in this paper.It indicated that the monsoon during summer tropical monsoon onset over South China Sea is the result of the westerly flow over middle part of South China Sea,which is from the new generated cyclone formed in north subtropical high entering into South China Sea,converged with the tropical southwesterly flow recurred by the intensified cross-equatorial flow. 相似文献
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The interactions among the Asian-Pacific monsoon subsystems have significant impacts on the climatic regimes in the monsoon region and even the whole world. Based on the domestic and foreign related research, an analysis is made of four different teleconnection modes found in the Asian-Pacific monsoon region, which reveal clearly the interactions among the Indian summer monsoon (ISM), the East Asian summer monsoon (EASM), and the western North Pacific summer monsoon (WNPSM). The results show that: (1) In the period of the Asian monsoon onset, the date of ISM onset is two weeks earlier than the beginning of the Meiyu over the Yangtze River Basin, and a teleconnection mode is set up from the southwestern India via the Bay of Bengal (BOB) to the Yangtze River Basin and southern Japan, i.e., the "southern" teleconnection of the Asian summer monsoon. (2) In the Asian monsoon culmination period, the precipitation of the Yangtze River Basin is influenced significantly by the WNPSM through their teleconnection relationship, and is negatively related to the WNPSM rainfall, that is, when the WNPSM is weaker than normal, the precipitation of the Yangtze River Basin is more than normal. (3) In contrast to the rainfall over the Yangtze River Basin, the precipitation of northern China (from the 4th pentad of July to the 3rd pentad of August) is positively related to the WNPSM. When the WNPSM is stronger than normal, the position of the western Pacific subtropical high (WPSH) becomes farther northeast than normal, the anomalous northeastward water vapor transport along the southwestern flank of WPSH is converged over northern China, providing adequate moisture for more rainfalls than normal there. (4) The summer rainfall in northern China has also a positive correlation with the ISM. During the peak period of ISM, a teleconnection pattern is formed from Northwest India via the Tibetan Plateau to northern China, i.e., the "northern" teleconnection of the Asian summer monsoon. The 相似文献
11.
高分辨率卫星实测资料揭示的近年亚洲热带夏季风爆发进程 总被引:1,自引:0,他引:1
利用高分辨率卫星观测资料,从气候态角度分析了亚洲热带夏季风爆发特征。研究表明,亚洲热带夏季风最先在中南半岛西部爆发,随后在整个中南半岛和孟加拉湾东部,然后扩大至孟加拉湾西部和南海。夏季风爆发后,与孟加拉湾和南海相比,中南半岛雨量增强形势不明显。第26—28候(即5月第2候—5月第4候)是亚洲热带夏季风的爆发阶段。整个爆发过程,低层风场的时空演变与对流降水相对应,海表温度场增温较海表风场提早约1候左右;华南地区以锋面降水为主,即副热带季风降水。采用对流降水和海表上空10 m风场分别代表夏季风降水和盛行风向的时空演变特征较常规资料更为准确、精细。 相似文献
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南海夏季风爆发与大气对流低频振荡的年际变化 总被引:8,自引:0,他引:8
根据1980~1991年云顶黑体温度(TBB)相位和强度的变化确定了南海夏季风爆发的时间,分析研究了夏季风爆发期间TBB场和850hPa风场的变化过程及其与海温的关系。结果表明:南海夏季风爆发平均时间是5月第4候,它爆发的时间和强度有显著的年际变化,并与大气的低频振荡及前期海洋的热力状况有密切关系。南海夏季风爆发早年(4月第6候),副热带高压较弱,撤离南海较快,从赤道东印度洋到赤道西太平洋,大气对流活动较强,夏季风爆发南海早于孟加拉湾,季风爆发时90~100°E区域过赤道气流显著加强。夏季风爆发晚年(6月第1候)情况相反。南海夏季风爆发早晚与大气30~60天振荡到达南海的位相有关,前冬和早春南海海温的高低和4月中旬至5月中南半岛强对流区的出现时间,是南海夏季风爆发年际变化的前期征兆。根据前冬南海海温预测1998年南海夏季风爆发的时间和强度与实际相符。 相似文献
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By using 40-year NCEP reanalysis daily data (1958-1997), we have analyzed the climatic
characteristics of summer monsoon onset in the South China Sea (105°E ~ 120°E, 5°N ~ 20°N, to be simplified
as SCS in the text followed) pentad by pentad (5 days). According to our new definition, in the monsoon area of
the SCS two of the following conditions should be satisfied: 1) At 850hPa, the southwest winds should be greater
than 2m/s. 2) At 850 hPa, θse should be greater than 335°K. The new definition means that the summer
monsoon is the southwest winds with high temperature and high moisture. The onset of the SCS summer monsoon
is defined to start when one half of the SCS area (105°E ~ 120°E,5°N ~ 20°N) is controlled by the summer
monsoon. The analyzed results revealed the following: 1) The summer monsoon in the SCS starts to build up abruptly
in the 4th pentad in May. 2) The summer monsoon onset in the SCS is resulted from the development and
intensification of southwesterly monsoon in the Bay of Bengal. 3) The onset of the summer monsoon and
establishment of the summer monsoon rainfall season in the SCS occur simultaneously. 4) During the summer
monsoon onset in the SCS, troughs deepen and widen quickly in the lower troposphere of the India; the
subtropical high in the Western Pacific moves eastward off the SCS in the middle troposphere; the easterly
advances northward over the SCS in the upper troposphere. 相似文献
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EAST ASIA SUMMER MONSOON ONSET DATE CALCULATED FROM OBSERVED, REANALYZED AND COMBINED DAILY RAINFALL
In this paper, the East Asia summer monsoon onset date lines in East China are calculated by the definition similar to the traditional one, with the ECMWF reanalyzed 850 hPa daily wind and observed, reana-lyzed and combined daily rainfall during 1980~1993. To make the onset date line as close as possible to the previous work, the earliest onset date limits have to be applied for the regions with different latitude and the daily mean datasets have to be smoothed by space before calculation, therefore their space-resolution is reduced to about 3 longitude ×1°latitude. The results show that the multiyear mean summer monsoon onset date lines are quite similar to each other. Compared with the one from the reanalysis, the 14-year average onset date line form combination is obviously improved in the southern Sichuan Basin and the correlation between observed and combined onset date is also slightly higher over the Huaihe valley and Northeast China. Since daily rainfall combination also improved the long term daily mean and standard deviation through the pentad CMAP, if no better daily dataset is available, such a kind of daily rainfall combination can be used to get reasonable result in the Indian monsoon region without sufficient observatories or over the North Pacific without any ground observation at all in future study. 相似文献
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采用NCEP/NCAR再分析资料、FY2E-TBB及台站降水资料,对2011年南海夏季风爆发前后的环流特征进行分析。结果表明:2011年强对流活动由孟加拉湾扩展到南海地区,同时伴随着南亚高压移至中南半岛北部,西太平洋副热带高压向东撤出南海地区,南海夏季风于5月第4候(第28候)爆发;季风爆发后,印度-孟加拉湾季风槽形成,南海地区低空开始盛行西南气流,并伴有对流降水的发展和温、湿等要素的突变。随着季风活动的推进,我国雨带北抬,长江中下游一带进入梅雨期,出现降水大值区。通过分析发现长江中下游梅雨与南海夏季风均受副热带高压影响,且两者的强度为显著的负相关关系,梅雨开始时间与南海夏季风爆发时间呈显著的正相关关系。2011年南海夏季风偏弱,爆发时间偏早,长江中下游梅雨强度偏强,入梅时间异常偏早。 相似文献
17.
This paper presents a study on the temporal and spatial variations of the precipitation over the area of the South China Sea (SCS) during the monsoon onset period. The data used are from the Tropical Rainfall Measuring Mission (TRMM) observations between April and June over the nine years from 1998 to 2006. This study focuses on the central and northern part of South China Sea (110-120°E, 10-20°N). Based on the observations, the 27th pentad is selected as the occurrence time of the SCS monsoon onset. The conclusions are as follows. (1) After the monsoon onset, the specific area, defined as the ratio of the number of pixels with certain type of precipitation to the number of total pixels, extends significantly for both convective and stratiform rain, with the latter having a larger magnitude. The specific rainfall, defined as the ratio of the amount of certain type of precipitation to the total amount of precipitation, decreases for convective rain and increases for stratiform rain. (2) Results also show significant increase in heavy rain and decrease in light rain after the monsoon onset. (3) Changes are also observed in the rainfall horizontal distributions over the SCS before and after the monsoon onset, manifested by the relocation of precipitation minima for both convective and stratiform rain. (4) After the monsoon onset, the variability in characteristics of precipitation vertical structure increases significantly, leading to more latent heat release and consequently deeper convection. Meanwhile, the bright-band altitude of stratiform precipitation is also elevated. 相似文献
18.
东亚夏季风降水中30—60天低频振荡 总被引:16,自引:1,他引:16
通过对东亚夏季风区域30年候降水量的分析研究可以看到,降水中30—60天低频振荡的季节变化与总的季风降水的季节变化具有明显的锁相关系,对季风雨带位置的出现起着重要的调制作用;降水低频振荡的年际变化对梅雨的年际变化也起着重要的调制作用;降水低频振荡呈现明显的由南向北的经向传播。 相似文献
19.
南海夏季风爆发的一般特征是南亚高压移至中南半岛北部;西太平洋副热带高压连续向东撤出南海地区,移到120°E以东的热带洋面上;高(低)空东北(西南)气流占据南海大部分地区,相应的105°E附近的越赤道气流建立,南海季风槽形成并同时伴有对流降水的发展和温、湿等要素的突变。国家气候中心的监测表明,2007年南海夏季风于5月第5候爆发。该年季风爆发后,虽然源自热带地区的低空西南气流迅速占据南海上空,高空盛行东北气流,且南亚高压西移至中南半岛上空,但对流、高度场以及降水场的突变特征均很不明显,表现为季风爆发后南海上空的对流依然偏弱,副高没有马上撤离南海,同时华南地区的降水量也没有迅速增强。因此,2007年南海夏季风爆发前后大气环流的变化特征具有非典型性。 相似文献
20.
2007年汛期淮河流域连续性大暴雨TBB场分析 总被引:6,自引:1,他引:5
利用水平分辨率0.1°×0.1°经纬度FY-2C卫星TBB网格资料、连续性强降水过程和最强降水时段的加强加密降水资料(其中,安徽临泉县迎仙站日降水破安徽省日最大降水纪录),对应分析TBB平均场分布特征及其演变特点,揭示强降水云团生消史与暴雨发展的内在联系.结果表明:TBB低值区与淮河流域强暴雨落区有明显的对应关系,TBB值减小过程与雨强增强过程比较一致,TBB梯度大值区在某地长时间维持将产生长时间强降水.源源不断的来自南海经广西沿着副高西北侧向东北方向伸展的水汽输送,与西风槽不断带来的新鲜冷空气在淮河流域相汇,对淮河流域强降水云系的生成、发展和维持起着重要作用.同时,在此阶段TBB 低值区在淮河流域一带稳定少动,南北摆动幅度小,时生时伏的变化,造成淮河流域天气53 年以来全线致洪暴雨重大事件. 相似文献