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1.
东亚地区夏季风爆发过程 总被引:72,自引:5,他引:67
利用中国194站1961~1995年日降水资料及NCEP1979~1997年候格点降水资料,探讨了亚洲地区自春到夏的雨季开始分布。结果表明,东亚地区自春到夏存在副热带季风雨季开始和热带季风雨季开始。前者于4月初开始于华南北部和江南地区,随后向南和向西南扩展,于4月末扩展到华南沿海和中南半岛,这个雨带主要是冷空气和副热带高压西侧转向的SW风以及南亚地区冬春副热带南支西风槽中西风汇合而形成的,是副热带季风雨季开始。后者是南海热带季风爆发后使原来由江南移到华南沿岸的副热带季风雨带随副热带高压北进而北进,前汛期雨季进入盛期,江南出现第二次雨峰,形成梅雨期和江淮及华北雨季。同时,热带季风雨带也自东向西传播到达南亚地区而形成热带季风雨季。还讨论了1998年东亚地区夏季风爆发过程,指出南海夏季风爆发期的季风由副高北侧形成的新生气旋进入南海造成南海中部西风和南海越赤道气流转向的SW季风加强汇合而形成,因而是东亚季风系统中环流系统季节变化造成的,和印度季风无关。在南海季风爆发期阿拉伯海仍由副热带反气旋控制,南亚仍是上述副热带反气旋北侧NW风南下后转向的偏西副热带气流所控制,索马里低空急流仍未爆发,赤道西风并未影响南海。 相似文献
2.
关于东亚副热带季风若干问题的讨论 总被引:25,自引:4,他引:21
利用NCEP/NCAR再分析格点资料、TRMM卫星降水资料、中国东部站点降水资料和CMAP降水资料,重点讨论了东亚副热带季风雨季的起始时间、建立特征及其和南海夏季风的关系,同时也讨论了东亚副热带季风的可能机制.结果表明:(1)东亚副热带季风雨季于3月底-4月初(第16-18候)在江南南部和华南北部首先开始,伴随着降水的开始是偏南风的增强和对流性降水的显著增加,华南前汛期开始.(2)东亚副热带季风雨季的建立早于热带季风雨季,在热带季风建立后两者的雨带、强西南风带、强垂直运动带、强低空水汽辐合带均是分离的,南海热带季风在其建立后,与东亚副热带季风发生相互作用,促使副热带季风雨带季节性北进,两者共同影响中国的旱涝.(3)3月中下旬,东亚大陆(包括青藏高原)上空大气由冷源转为热源,东亚大陆与西太平洋之间的纬向热力差异及其相应的温度和气压对比均发生反转.东亚大陆(包括青藏高原)的动力和热力作用究竟是否是东亚副热带季风雨带提前建立的机制值得进一步研究.文章最后讨论了有关东亚副热带季风的共识与分歧. 相似文献
3.
中国气象科学研究院曾长期组织和从事东亚季风及其对中国天气和旱涝影响的研究。该文对中国气象科学研究院在东亚季风研究方面取得成果进行综述, 并回顾了20世纪50年代以来国内有关季风的研究活动, 也回顾了影响我国天气气候、东亚季风环流系统的提出及其后续的有关东亚和印度季风系统的相互作用, 引发中国大陆暴雨生成的水汽输送, 表达中国大陆季风活动的季风指数设计等研究结果。综述了南海夏季风爆发、梅雨开始、中国雨季开始及传播等有关研究成果; 东亚季风系统中副热带地区低频振荡纬向和经向传播特征及与赤道地区不同之处, 东亚低频振荡对El Ni?o形成及夏季东亚热带和副热带季风爆发的可能影响, 东亚热带和副热带季风低频振荡对中国天气气候的影响等有关成果; 亚洲地区大气热源的计算及其分布, 青藏高原夏季热源对东亚夏季风及降水的可能影响, 青藏高原冬季冷源对El Ni?o生成的可能影响等有关成果; 东亚季风及降水的年际变化特征, 准4年年际振荡的分析及与ENSO形成间的相互作用, 极地对东亚夏季降水的影响及东亚季风年代际变化特征等成果。综述东亚季风系统形成的可能机制, 特别是亚洲大陆—西太平洋海陆热力差异及非洲、印度半岛、中南半岛及澳大利亚陆地与周围海洋对冬夏季风形成、印度和东亚季风系统形成、南海夏季风形成作用的结果。 相似文献
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资料分析显示,与850 hPa风场相比,地面风的变化能更好地表征亚洲各季风系统的特征。基于地面风的季节性反转和降水的显著变化所构建的亚洲夏季风(ASM)爆发指数和等时线图表明:亚洲热带夏季风(TASM)在5月初首先在孟加拉湾(BOB)东南部爆发后不是向西传播,而是向东经中印半岛向东推进,于5月中到达中国南海(SCS),6月初到达热带西北太平洋。印度夏季风的表面低压系统源于近赤道阿拉伯海地区,于6月初到达印度西南部喀拉拉邦,印度夏季风随之爆发。亚洲副热带夏季风(STASM)5月初在西北太平洋日本本州东南的海区发生后向西南伸展,于6月初与南海季风降水区连接,形成东北—西南向雨带,夏季风在中国东南沿海登陆,日本的“梅雨”(Baiu)开始。6月中该雨带向北到达长江流域和韩国,江淮梅雨和韩国的“梅雨”(Changma) 开始。本文还回顾了亚洲热带夏季风爆发的动力学研究的若干近期进展。春季青藏高原和南亚海陆分布的联合强迫作用使海表温度(SST)在BOB中东部形成短暂但强盛的暖池,在高层南亚高压的抽吸作用下,常伴有季风爆发涡旋(MOV)发展,使冬季连续带状的副高脊线在孟加拉湾东部断裂,导致亚洲热带季风首先在BOB爆发。BOB东/西部有东/西风型垂直切变,利于激发/抑制对流活动,并增加/减少海洋向大气的表面感热加热,从而使得亚洲夏季风爆发的向西传播在BOB西海岸遇到屏障。季风爆发逐渐向东伸展引发南海和热带西太平洋夏季风相继爆发。季风降水释放的强大潜热使南亚高压发展西伸,纬向非对称位涡强迫显著增强;在阿拉伯半岛强烈的表面感热加热所诱发的中层阿拉伯反气旋的共同作用下,位于阿拉伯海近赤道的低压系统北移发展成为季风爆发涡旋,导致印度季风爆发。由此可见,历时约一个月的亚洲热带夏季风爆发的三个阶段(孟加拉湾、南海和印度季风爆发)是发生在特定的地理环境下受特定的动力—热力学规律驱动的接续过程。 相似文献
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6.
亚洲热带夏季风的首发地区和机理研究 总被引:28,自引:5,他引:28
文中分析了多年逐候平均 85 0hPa风场和黑体辐射温度等物理量的时空演变 ,结果表明 ,90°E以东的孟加拉湾、中南半岛和南海是亚洲热带夏季风首先爆发的地区 ,爆发时间在 2 7~ 2 8候 ,具有突发性和同时性。 90°E以西的印度半岛和阿拉伯海是热带夏季风爆发较晚的地区 ,季风首先在该区 10°N以南爆发 ,时间约在 30~ 31候 ,然后向北推进 ,6月末在全区建立 ,爆发过程具有渐进性。机制分析表明 ,由于 110~ 12 0°E的中高纬东亚大陆在春季和初夏地面感热通量、温度和气压的迅速变化 ,使热带低压带首先在该处冲破高压带 ,生成大陆低压 ,并引导西南气流在 90°E以东地区首先建立。在 90°E以西的印度半岛地区 ,地面感热通量在 4~ 5月间几乎没有明显变化 ,因而印度季风比南海季风晚爆发约 1个月。由此得出 ,90°E是东亚夏季风和南亚夏季风的分界线。此外 ,还着重探讨了南亚高压的季节变化与亚洲热带夏季风爆发的时间联系。发现南亚高压中心位置与亚洲热带夏季风爆发时间有较好的对应关系。南亚高压中心跳过 2 0°N时 ,南海夏季风爆发 ,跳过 2 5°N时 ,印度夏季风在其南部爆发。将用上述方法确定的爆发时间与用其他方法确定的爆发时间相比较 ,发现它们在南海地区有较好的一致性 ,在印度地区略有差异。 相似文献
7.
利用南海季风试验分析场和NCAR向外长波辐射通量(OLR)资料研究了1998年孟加拉湾季风和南海季风爆发期间副热带环流的大尺度和天气尺度特征,探讨了孟加拉湾季风爆发与南海季风爆发之间的物理联系及孟加拉湾季风气旋的对流凝结潜热释放对副热带高压“撤出”南海的影响。结果表明,1998年5月爆发的东亚季风展现出典型的从孟加拉湾地区东传发展到南海地区的过程。随着孟加拉湾季风爆发和对流活动增强、北移,南海北部出现了低层西风和对流活动,领先于副热带高压在南海地区减弱和撤退。结果还显示南海北部地区的对流凝结加热有助于该地区经向温度梯度的反转,在热成风关系的制约下南海上空副热带高压脊面的垂直倾斜由冬季型转向夏季型,季风爆发。 相似文献
8.
孟加拉湾热源对亚洲夏季风环流系统的影响 总被引:8,自引:5,他引:8
利用 1951—2000年NCEP/NCAR再分析逐日及月平均资料和我国 160个测站 1951—2000年月降水量资料,计算了夏季大气热源气候分布,分析了夏季孟加拉湾地区热源年际异常及亚洲季风环流系统的响应,以及夏季孟加拉湾地区热源与中国夏季降水的年际关系。结果表明:夏季亚洲季风区最强的热源中心位于孟加拉湾东北部一带。当孟加拉湾热源异常强 (弱 )时,南亚高压偏西 (东 ),西太平洋副热带高压位置偏东(西);印度夏季风偏强 (弱),东亚热带季风偏弱 (强 )。孟加拉湾热源异常对南亚高压、南亚季风、副热带高压的影响显著,对东亚热带季风的影响不显著。夏季孟加拉湾热源与同期长江以南、华南东部部分地区降水呈明显负相关,而与西南到华南西部地区降水呈明显正相关。 相似文献
9.
东亚热带季风与副热带季风降水特征研究的回顾与展望 总被引:3,自引:1,他引:2
东亚季风既包含热带季风又包含副热带季风,他们之间存在的相互作用直接影响我国大范围旱涝灾害。东亚热带季风和东亚副热带季风作为两种性质不同的季风,其形成原因及其主要天气系统截然不同,对应的热带季风降水和副热带季风降水在结构、性质上自然也存在很大的差异。简要回顾我国气象学家在东亚热带季风降水及东亚副热带季风降水方面的研究成果,概述最近关于东亚副热带季风研究的热点问题,引证了利用星载测雨雷达对南海地区降水性质的部分研究结果,并对进一步利用星载测雨雷达资料开展季风及其降水研究进行了展望。 相似文献
10.
梅雨期及其前后东亚地区的径向环流结构 总被引:2,自引:0,他引:2
本文分析了1983年江淮流域入梅前、梅雨期以及出梅后东亚地区各期平均的径向环流结构及其演变特征。在不同时期,印度热带季风环流和东亚热带及副热带季风环流具有显著差异。研究指出,江淮流域梅雨是亚洲夏季三个季风系统相互作用的结果,是东亚副热带季风系统中径向经向环流上升支中的产物,同时又与其它两个季风系统密切相关,梅雨结束则与印度热带季风环流减弱南撤、西太平洋高压加强西伸、东亚副热带季风环流北上有关。 相似文献
11.
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
12.
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
13.
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
14.
利用1979—2014年ERA-Interim逐月的风场、海平面气压场和位势高度场等再分析资料以及中国160站降水观测资料,采用回归分析等方法分析了盛夏(7、8月)南海(South China Sea, SCS)低空越赤道气流(Cross-Equatorial Flow,CEF)的变化及其与东亚夏季风的联系,结果表明:盛夏南海低空越赤道气流(SCEF)强度指数与南海夏季风强度指数呈显著的正相关关系,与东亚副热带夏季风强度指数呈显著的负相关关系。当盛夏SCEF偏强(弱)时,亚洲热带低压及西太平洋赤道辐合带增强(减弱),西太平洋副热带高压强度减弱(增强)、东撤(西伸),南海北部和西北太平洋地区为明显的气旋式(反气旋式)环流异常,使得南海夏季风增强(减弱)和东亚副热带夏季风减弱(增强)。此外,当盛夏SCEF偏强时,由于东亚副热带夏季风减弱,我国华南地区为东北风异常,华北地区为偏南风异常,受其影响,我国华南地区为显著的水汽辐合区,华中地区为显著的水汽辐散区,使得盛夏华南地区降水增多,华中地区降水减少;反之亦然。 相似文献
15.
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
16.
利用海气耦合和大气气候模式研究东亚冬季风异常对夏季环流的影响, 结果表明, 东亚冬季风异常对于后期环流及海洋状态异常都起了很大的作用.一般情况下, 强的冬季风与后期弱的东亚夏季风和较强的南海季风相对应.与强(弱)冬季风异常相关的风应力的改变可以使热带太平洋海温从冬季至夏季呈现La Nina (El Nio)型异常分布.试验得到的由冬季风异常所产生的海洋及夏季环流的变化与实况是相当接近的.在异常的冬季风偏北风分量强迫下, 西太平洋上形成的偏差气旋环流在夏季已不存在, 这时东亚夏季风反而增强.而冬季赤道西风分量所产生的影响, 则在西太平洋上形成显著的偏差气旋环流, 使东亚副热带夏季风减弱, 南海夏季风加强.对于东亚大气环流而言, 与强弱冬季风对应的热带海洋海温异常强迫下, 不仅是冬季, 后期春季和夏季环流的特征都能得到很好的模拟.但是从分区看, 西太平洋暖池区的海温异常比东太平洋更为重要.单纯的热带中东太平洋的海温异常对东亚大气环流的影响主要表现在冬季, 对后期的影响并不十分清楚.整个热带海洋的异常型分布(不论是El Nio还是La Nia)型, 对冬夏季风的影响是重要的, 而单纯的某个地区的海温异常都比它的整体影响要小.从试验结果看, 海温在大尺度冬夏季环流的隔季相关中起了十分重要的作用. 相似文献
17.
HE Jinhai ZHAO Ping ZHU Congwen ZHANG Renhe TANG Xu CHEN Longxun ZHOU Xiuji 《Acta Meteorologica Sinica》2008,22(4):419-434
Based on NCEP/NCAR gridded reanalysis, TRMM precipitation data, CMAP, and rainfall observations in East China, a study is conducted with focus on the timing and distinctive establishment of the rainy season of the East Asian subtropical monsoon (EASM) in relation to the South China Sea (SCS) tropical summer monsoon (SCSM). A possible mechanism for the EASM is investigated. The results suggest that 1) the EASM rainy season begins at first over the south of the Jiangnan region to the north of South China in late March to early April (i.e., pentads 16-18), and then the early flooding period in South China starts when southerly winds enhance and convective rainfall increases pronouncedly; 2) the establishment of the EASM rainy season is earlier than that of its counterpart, the SCSM. The EASM and the SCSM each is featured with its own independent rain belt, strong southwesterly wind, intense vertical motion, and robust low-level water vapor convergence. The SCSM interacts with the EASM, causing the EASM rainy belt to move northward. The two systems are responsible for the floods/droughts over the eastern China; and 3) in mid-late March, the eastern Asian landmass (especially the Tibetan Plateau) has its thermal condition changing from a cold to a heat source for the atmosphere. A reversal of the zonal thermal contrast and related temperature and pressure contrasts between the landmass and the western Pacific happens. The argument about whether or not the dynamic and thermal effects of the landmass really act as a mechanism for the earlier establishment of the EASM rain belt is discussed and to be further clarified. Finally, the article presents some common understandings and disagreements regarding the EASM. 相似文献
18.
The East Asian summer monsoon: an overview 总被引:38,自引:1,他引:38
Summary The present paper provides an overview of major problems of the East Asian summer monsoon. The summer monsoon system over East Asia (including the South China Sea (SCS)) cannot be just thought of as the eastward and northward extension of the Indian monsoon. Numerous studies have well documented that the huge Asian summer monsoon system can be divided into two subsystems: the Indian and the East Asian monsoon system which are to a greater extent independent of each other and, at the same time, interact with each other. In this context, the major findings made in recent two decades are summarized below: (1) The earliest onset of the Asian summer monsoon occurs in most of cases in the central and southern Indochina Peninsula. The onset is preceded by development of a BOB (Bay of Bengal) cyclone, the rapid acceleration of low-level westerlies and significant increase of convective activity in both areal extent and intensity in the tropical East Indian Ocean and the Bay of Bengal. (2) The seasonal march of the East Asian summer monsoon displays a distinct stepwise northward and northeastward advance, with two abrupt northward jumps and three stationary periods. The monsoon rain commences over the region from the Indochina Peninsula-the SCS-Philippines during the period from early May to mid-May, then it extends abruptly to the Yangtze River Basin, and western and southern Japan, and the southwestern Philippine Sea in early to mid-June and finally penetrates to North China, Korea and part of Japan, and the topical western West Pacific. (3) After the onset of the Asian summer monsoon, the moisture transport coming from Indochina Peninsula and the South China Sea plays a crucial “switch” role in moisture supply for precipitation in East Asia, thus leading to a dramatic change in climate regime in East Asia and even more remote areas through teleconnection. (4) The East Asian summer monsoon and related seasonal rain belts assumes significant variability at intraseasonal, interannual and interdecadal time scales. Their interaction, i.e., phase locking and in-phase or out-phase superimposing, can to a greater extent control the behaviors of the East Asian summer monsoon and produce unique rythem and singularities. (5) Two external forcing i.e., Pacific and Indian Ocean SSTs and the snow cover in the Eurasia and the Tibetan Plateau, are believed to be primary contributing factors to the activity of the East Asian summer monsoon. However, the internal variability of the atmospheric circulation is also very important. In particular, the blocking highs in mid-and high latitudes of Eurasian continents and the subtropical high over the western North Pacific play a more important role which is quite different from the condition for the South Asian monsoon. The later is of tropical monsoon nature while the former is of hybrid nature of tropical and subtropical monsoon with intense impact from mid-and high latitudes. 相似文献
19.
亚洲夏季风爆发的深对流特征 总被引:9,自引:1,他引:9
文中应用NOAA卫星反演的1980~1995年候平均对流层上部水汽亮温(BT)资料、向外长波辐 射(OLR)资料和美国NMC全球分析850 hPa风资料与美国CMAP降水资料作了对比分析,发现B T能够较好地反映中低纬度地区的深对流降水,偏南风场辐合区与深对流降水有比较一致的 关系,而OLR不能反映热带外地区的对流降水。BT资料所具有的这一特征可以应用于亚洲夏 季风爆发过程的深对流特征分析。BT描述深对流的临界值是244 K。亚洲季风区是全球深对 流季节变化范围和强度最大的地区。赤道外地区的夏季风爆发可以定义为来自热带地区深对 流的季节扩张。中南半岛上的夏季风对流发生在南海夏季风爆发之前。华南前汛期深对流是 中低纬系统相互作用的结果。第28候,南海夏季风的突然爆发在降水、风场和卫星反演 的深对流特征上都有明确的反映。南海夏季风爆发后,印度夏季风对流由南向北逐渐爆发, 青藏高原东侧和中国东部沿海的夏季风对流向北推进早于中国中部地区。 相似文献