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1.
亚洲夏季风爆发的基本气候特征分析   总被引:3,自引:0,他引:3  
柳艳菊  丁一汇 《气象学报》2007,65(4):511-526
利用统一的亚洲热带夏季风爆发指标,重新制作了季风爆发日期的推进图,确证了亚洲热带夏季风最早在热带东印度洋与中印半岛中南部爆发的观点,这发生在26候(5月10日前后),28候(5月20日前后)在南海地区相继爆发,这两个地区的爆发是属同一季风系的不同爆发阶段。以后通过对海陆热力对比、季节内振荡等多方面的分析,对夏季风的爆发机制问题进行了深入的研究,提出了气候学意义下影响亚洲热带夏季风爆发的关键影响因子。在此基础上,给出了夏季风最早在热带东印度洋-中印半岛-南海地区爆发机理的一种概念模式图,即大气环流的季节进程是季风爆发的背景条件;而中印半岛及其邻近地区对流活动和感热与潜热加热的迅速增强与北推、印缅槽的强烈加深,以及高原东部地区的西风暖平流作用是夏季风爆发的主要驱动力,其结果是使经向温度梯度首先在这个地区反向并建立强的上升运动区,使热带季风和降水迅速发展和加强;来自不同源地的低频30—60 d和10—20 d季节内振荡的锁相则是夏季风爆发的一种触发因子,正是这些因子的共同作用导致了亚洲热带夏季风在这个地区的最早爆发。  相似文献   

2.
The onset process of the tropical eastern Indian Ocean (TEIO) summer monsoon (TEIOSM) and its relationship with the cross-equatorial flows are investigated via climatological analysis. Climatologically, results indicate that the earliest onset process of the Asian summer monsoon occurs over the TEIO at pentad 22 (April 15–20). Unlike the abrupt onset of the South China Sea (SCS) summer monsoon, the TEIOSM onset process displays a stepwise advance. Moreover, a close relationship between the TEIOSM development and the northward push of the cross-equatorial flows over 80–90E is revealed. A difference vorticity center, together with the counterpart over the southern Indian Ocean, constitutes a pair of difference cyclonic vortices, which strengthens the southwesterly wind over the TEIO and the northerly wind to the west of the Indian Peninsula from the end of March to late May. Therefore, the occurrence of the southwesterly wind over the TEIO is earlier than its counterpart over the tropical western Indian Ocean, and the cross-equatorial flows emerge firstly over the TEIO rather than over the Somali area. The former increases in intensity during its northward propagation, which provides a precondition for the TEIOSM onset and its northward advance.  相似文献   

3.
关于南海夏季风建立的大尺度特征及其机制的讨论   总被引:28,自引:3,他引:25  
使用1998年南海季风试验期间高质量资料和NCEP/NCAR40年再分析资料分析了南海季风建立前后的大尺度环流特征和要素的突变及爆发过程。发现南亚高压迅速地从菲律宾以东移到中南半岛北部,印缅槽加强,赤道印度洋西风加强并向东向北迅速扩展和传播,以及相伴随的中低纬相互作用和西太平洋副高连续东撤是南海夏季风建立的大尺度特征,与此同时,亚洲低纬地区的南北温差和纬向风切变也发生相应的突变。数值实验结果指出,印度半岛地形的陆面加热作用在其东侧激发的气旋性环流对于印缅槽的加强有重要作用,并进而有利于南海夏季风先于印度夏季风爆发。  相似文献   

4.
Since the early or late onset of the South China Sea summer monsoon (SCSM) has a large impact on summer monsoon rainfall in East Asia, the mechanism and process of early or late onset of the SCSM are an worthy issue to study. In this paper, the results analyzed by using the observed data show that the onset date and process of the SCSM are closely associated with the thermal state of the tropical western Pacific in spring. When the tropical western Pacific is in a warming state in spring, the western Pacific subtropical high shifts eastward, and twin cyclones are early caused over the Bay of Bengal and Sumatra before the SCSM onset. In this case, the cyclonic circulation located over the Bay of Bengal can be early intensified and become into a strong trough. Thus, the westerly flow and convective activity can be intensified over Sumatra, the Indo-China Peninsula and the South China Sea (SCS) in mid-May. This leads to early onset of the SCSM. In contrast, when the tropical western Pacific is in a cooling state, the western Pacific subtropical high anomalously shifts westward, the twin cyclones located over the equatorial eastern Indian Ocean and Sumatra are weakened, and the twin anomaly anticyclones appear over these regions from late April to mid-May. Thus, the westerly flow and convective activity cannot be early intensified over the Indo-China Peninsula and the SCS. Only when the western Pacific subtropical high moves eastward, the weak trough located over the Bay of Bengal can be intensified and become into a strong trough, the strong southwesterly wind and convective activity can be intensified over the Indo-China Peninsula and the SCS in late May. Thus, this leads to late onset of the SCSM. Moreover, in this paper, the influencing mechanism of the thermal state of the tropical western Pacific on the SCSM onset is discussed further from the Walker circulation anomalies in the different thermal states of the tropical western Pacific.  相似文献   

5.
中南半岛地区热力特征对南海季风爆发的可能影响及机理   总被引:10,自引:1,他引:10  
利用1998年5月1日-8月31日南海季风试验(SCSMX)产1980年1月-1995年12月NCEP/NCAR候平均再分析资料,分析1998年和多年平均情况下南海夏季风爆发期间中南半岛地区热力特征,揭示该地区热状况的异常与南海夏季风爆发之间的可能联系,从而讨论引起南海夏季风爆发的可能机制。结果发现,南海季风爆发前中南半岛附近地区存在较强的持续地面感知加热并具有显的低频振荡特征,低层大气在中南半岛地区出现较强的暖中心,由此导致局地强的水平温度梯度和位势高度梯度,有利于加强该地区的西南风。南海季风爆发前中南半岛地区低层出现较强的辐合风,高层出现较强的辐散风,这种低层强的辐合,高层强的辐射散配置有利于垂直运动的发展,降水的加强,进而触发南海季风的爆发。对多年平均资料的分析也证实了1998年南海季风爆发过程中所具有的特征,并进一步发现南海季风爆发前中南半岛地区850hPa温度是逐渐增加的,且增温幅度大于南海地区上空,由此加强了中南半岛与南海之间的温差。另外,比纬圈温度偏差和位势高度偏差的分析中发现,南海季风爆发期间南海和中南半岛地区的副高东撤与中南半岛地区的增温和孟加拉湾低槽的向东扩展有关。  相似文献   

6.
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   

7.
亚洲夏季风爆发始于孟加拉湾,然后向中国南海和印度次大陆扩展,其过程约持续1个月。各地区夏季风爆发时间呈明显的年际变化。利用热带气旋资料和气象再分析资料,统计了1951-2010年孟加拉湾和中国南海夏季风爆发前后西北太平洋热带气旋、孟加拉湾气旋风暴活动和夏季风爆发的关系。结果表明,在孟加拉湾夏季风爆发过程中,共有36 a出现孟加拉湾气旋风暴,并且夏季风爆发偏早年出现风暴的几率最高,为80%。在孟加拉湾夏季风爆发偏早、正常和偏晚3种类型中,孟加拉湾风暴活动频率高峰期多出现在夏季风爆发前后几天内。并且在孟加拉湾风暴活动频率高峰出现前期,西北太平洋热带气旋最先出现活动频率高峰。孟加拉湾夏季风爆发前有40%-50%的年份西北太平洋出现热带气旋活动,其中,夏季风爆发偏早年,爆发前西北太平洋热带气旋活跃的时间偏早(4月第2候),且多活动在中国南海和菲律宾附近;爆发正常年,西北太平洋热带气旋活跃的时间为4月第4候,多活动在略偏东的海域;爆发偏晚年,西北太平洋热带气旋活跃的时间为5月初,活动区域最偏东。中国南海夏季风爆发过程中,60 a中共有29 a西北太平出现热带气旋,其中爆发偏早和正常年出现热带气旋的频率较高,并且热带气旋多出现在爆发当日和爆发后一段时间。整体来看,亚洲夏季风爆发前,西北太平洋热带气旋活动频率最先开始增强,然后孟加拉湾风暴开始活跃并伴随着孟加拉湾夏季风爆发,夏季风爆发偏早和正常年,孟加拉湾夏季风爆发后,西北太平洋热带气旋再次增强,中国南海夏季风爆发。   相似文献   

8.
Using the CCM3/NCAR, a series of numerical experiments are designed to explore the effect of ocean-land interlaced distributions of Africa-Arabian Sea-India Peninsula-Bay of Bengal (BOB)-Indo-China Peninsula-South China Sea on the formation of the Asian summer monsoon circulation (ASMC). The results show that the thermal difference between African or Indian Subcontinent and nearby areas including the Indian Ocean, Arabian Sea, and part of BOB is the primary mechanism that maintains the Indian monsoon circulation. In the experiment getting rid of these two continents, the Indian monsoon system (IMS) members, i.e., the Somali cross-equatorial jet (40°E) and the southwesterly monsoon over the Arabian Sea and BOB, almost disappear. Moreover, the Hadley circulation weakens dominantly. It also proves that Africa has greater effect than Indian Subcontinent on the IMS. However, the existence of Indo-China Peninsula and Australia strengthens the East Asian monsoon system (EAMS). The thermal contrast between Indo-China Peninsula and SCS, Australia and western Pacific Ocean plays an important role in the formation of the tropical monsoon to the south of the EAMS. When the Indo-China Peninsula is masked in the experiment, the cross-equatorial flow (105°E and 125°E) vanishes, so does the southwesterly monsoon usually found over East Asia, and EAMS is enfeebled significantly. In addition, the impacts of these thermal contrasts on the distribution of the summer precipitation and surface temperature are investigated.  相似文献   

9.
Based on summarizing previous achievements and using data as long and new as possible, the onset characteristics of Asian summer monsoon and the role of Asian-Australian “land bridge” in the onset of summer monsoon are further discussed. In particular, the earliest onset area of Asian summer monsoon is comparatively analyzed, and the sudden and progressive characteristics of the onset of summer monsoon in different regions are discussed. Furthermore, the relationships among such critical events during the onset of Asian summer monsoon as the splitting of subtropical high belt over the Bay of Bengal (BOB), the initiation of convection over Indo-China Peninsula, the westward advance, reestablishment of South Asian High, and the rapid northward progression of convection originated from Sumatra in early summer are studied. The important impact of the proper collocation of the latent heating over Indo-China Peninsula and the sensible heating over Indian Peninsula on the splitting of the subtropical high belt, the deepening of BOB trough, the activating of Sri Lanka vortex (twin vortexes in the Northern and Southern Hemispheres), and the subsequent onset of South China Sea summer monsoon are emphasized.  相似文献   

10.
南海夏季风建立的模式诊断研究   总被引:5,自引:0,他引:5  
应用全球谱模式 (T42L9)对 1 986年和 1 987年个例进行了一系列有、无凝结潜热加热和地表感热以及地形作用的单因子敏感性数值预报试验 ,对预报模式输出的大气凝结潜热量和地面感热通量的时空变化特征进行了诊断分析。个例敏感性试验结果表明 ,大气凝结潜热对南海地区西南风的建立极为重要。诊断分析结果指出 ,在南海夏季风建立前 ,中南半岛地区是强大的凝结潜热加热区 ,远比印度半岛地区强。地形和中南半岛凝结潜热的共同作用可能是导致南海夏季风早于印度夏季风建立的重要原因。 1 987年 5月份在中南半岛地区的凝结潜热量比 1 986年明显偏低 ,直到 5月底 6月初才明显上升 ,这可能是该年南海夏季风建立晚的一个原因 ,中南半岛地区凝结潜热的变化可能是影响季风建立早晚的重要因子之一。  相似文献   

11.
This study depicts the sub-seasonal prediction of the South China Sea summer monsoon onset (SCSSMO) and investigates the associated oceanic and atmospheric processes, utilizing the hindcasts of the National Centers for Environmental Prediction (NCEP) Climate Forecast System version 2 (CFSv2). Typically, the SCSSMO is accompanied by an eastward retreat of the western North Pacific subtropical high (WNPSH), development of the cross-equatorial flow, and an increase in the east-west sea surface temperature (SST) gradient. These features are favorable for the onset of westerlies and strengthening of convection and precipitation over the South China Sea (SCS). A more vigorous SCSSMO process shows a higher predictability, and vice versa. The NCEP CFSv2 can successfully predict the onset date and evolution of the monsoon about 4 pentads (20 days) in advance (within 1–2 pentads) for more forceful (less vigorous) SCSSMO processes. On the other hand, the climatological SCSSMO that occurs around the 27th pentad can be accurately predicted in one pentad, and the predicted SCSSMO occurs 1–2 pentads earlier than the observed with a weaker intensity at longer leadtimes. Warm SST biases appear over the western equatorial Pacific preceding the SCSSMO. These biases induce a weaker-than-observed WNPSH as a Gill-type response, leading to weakened low-level easterlies over the SCS and hence an earlier and less vigorous SCSSMO. In addition, after the SCSSMO, remarkable warm biases over the eastern Indian Ocean and the SCS and cold biases over the WNP induce weaker-than-observed westerlies over the SCS, thus also contributing to the less vigorous SCSSMO.  相似文献   

12.
The onset of the Asian summer monsoon has been a focus in the monsoon study for many years. In this paper, we study the variability and predictability of the Asian summer monsoon onset and demonstrate that this onset is associated with specific atmospheric circulation characteristics. The outbreak of the Asian summer monsoon is found to occur first over the southwestern part of the South China Sea (SCS) and the Malay Peninsula region, and the monsoon onset is closely related to intra-seasonal oscillations in the lower atmosphere. These intra-seasonal oscillations consist of two low-frequency vortex pairs, one located to the east of the Philippines and the other over the tropical eastern Indian Ocean. Prior to the Asian summer monsoon onset, a strong low-frequency westerly emerges over the equatorial Indian Ocean and the low-frequency vortex pair develops symmetrically along the equator. The formation and evolution of these low-frequency vortices are important and serve as a good indicator for the Asian summer monsoon onset. The relationship between the northward jumps of the westerly jet over East Asia and the Asian summer monsoon onset over SCS is investigated. It is shown that the northward jump of the westerly jet occurs twice during the transition from winter to summer and these jumps are closely related to the summer monsoon development. The first northward jump (from 25–28N to around 30N) occurs on 8 May on average, about 7 days ahead of the summer monsoon onset over the SCS. It is found that the reverse of meridional temperature gradient in the upper-middle troposphere (500–200 hPa) and the enhancement and northward movement of the subtropical jet in the Southern Hemispheric subtropics are responsible for the first northward jump of the westerly jet.  相似文献   

13.
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   

14.
Based on the method of composite analysis, the onset process and preceding signs of summer monsoon over the South China Sea (SCS) is investigated. The result indicates that convection activities appear first over the Indo-China Peninsula prior to the onset of the monsoon, then around the Philippines just at the point of onset, implying that the convection activities around the Philippines serve as one of the reasons leading to the SCS monsoon onset. Before the SCS monsoon onset, the equatorial westerly over the Indian Ocean (75°E 95°E ) experiences noticeable enhancement and plays an important role on the SCS monsoon onset. It propagates eastward rapidly and causes the establishment and strengthening of equatorial westerly in the southern SCS, on the one hand, it results in the migration southward of the westerly on south side of the south-China stationary front by means of shift northeastward of the westerly and convection over the Bay of Bengal, on the other. Further study also shows that the intensification of equatorial westerly in the Indian Ocean (75°E 95°E) and the southern SCS is closely related to the reinforcement of the Southern-Hemisphere Mascarene high and Australian high, and cross-equatorial flow northward around Somali, at 85°E and 105°E, respectively.  相似文献   

15.
By using the 40-year NCEP (1958-1997) grid point reanalysis meteorological data, we analyzed the inter-decadal variation on the climatic characteristics of the onset of South China Sea summer monsoon. The results are as follows. (1) There was great difference on the onset date of the SCS summer monsoon between the first two decades and the last two decades. It was late on the 6th pentad of May for the first two decades and was on the 4th and 5th pentad of May for the next two decades. (2) Except for the third decade (1978-1987), the establishment of the monsoon rainfall was one to two pentads earlier than the onset of the summer monsoon in all other three decades. (3) The onset of the SCS monsoon is the result of the abrupt development and eastward advancement of the southwesterly monsoon over the Bay of Bengal. The four-decade analysis shows that there were abrupt development of the southwesterly monsoon over the Bay of Bengal between the 3rd and 4th pentad of May, but there was great difference between its eastward movement and its onset intensity. These may have important effect to the earlier or later onset of the SCS summer monsoon. (4) During the onset of the SCS summer monsoon, there were great difference in the upper and lower circulation feature between the first two and the next two decades. At the lower troposphere of the first two decades, the Indian-Burma trough was stronger and the center of the subtropical high was located more eastward. At the upper troposphere, the northward movement of the center of subtropical high was large and located more northward after it landed on the Indo-China Peninsula. After comparison, we can see that the circulation feature of the last two decades was favorable to the establishment and development of the SCS summer monsoon.  相似文献   

16.
蒙伟光  郑彬 《气象学报》2006,64(1):81-89
在对南海夏季风的爆发及中南半岛陆面过程的可能影响进行了诊断分析的基础上,应用MM5/NOAHLSM模式,研究了中南半岛陆气相互作用对2004年南海夏季风爆发过程的可能影响。结果发现:在南海夏季风爆发前,中南半岛南海地区低层气温差确实出现低值,甚至负值;尽管短期内中南半岛土壤湿度和降水的变化没有引起季风爆发日期的改变,但对季风爆发的强度有影响。土壤湿度和降水变化引起的干异常可导致地表感热通量的增大和地表温度的升高,致使中南半岛与南海之间低层的温差异常(负温差)减小,季风爆发强度减弱;不同的是,湿异常可引起季风爆发强度增强。这一结果说明,在南海夏季风爆发前期,中南半岛上空对流活动和降水异常及其引起的土壤湿度的异常变化在一定程度上会影响到季风爆发的过程。文章还比较了不同温湿地表条件下低层大气状态的差异和地表能量、水分平衡过程的不同,分析了陆气相互作用对季风活动产生影响的物理机制。  相似文献   

17.
In terms of the NCAR Community Climate Model (CCM3),the effect of the Indian Peninsulaon the course of the Asian tropical summer monsoon is simulated in this paper,and numericalexperimental results show that the Indian Peninsula plays a critical role in the establishmentprocess of the Asian tropical summer monsoon.When the CCM3 includes the Indian Peninsula,the model successfully simulates out the course of the Asian tropical summer monsoon,i.e.theSouth China Sea (SCS) summer monsoon at first bursts in middle May,while the Indian monsoonjust establishes until middle June.However when the Indian Peninsula topography is deleted in themodel,the Indian and SCS summer monsoons almost simultaneously establish in late May.Numerical results further indicate that in the former experiment the sensible heating of the IndianPeninsula warms the air above and produces evident temperature contrast between the peninsulaand its adjacent SCS and Bay of Bengal (BOB).which results in the strengthening and maintenanceof the BOB trough in the low-middle layer of the troposphere in the end of spring and early summerand thus the earliest establishment of the Asian tropical summer monsoon in the SCS in middleMay.However,the Indian summer monsoon just establishes until middle June when the strongwest wind over the Arabian Sea shifts northwards and cancels out the influence of the northwestflow behind the BOB trough.In the latter experiment the effect of Tibetan Plateau only produces avery weak BOB trough,and thus the SCS and Indian summer monsoons almost simultaneouslyestablish.  相似文献   

18.
In terms of the NCAR Community Climate Model (CCM3),the effect of the Indian Peninsula on the course of the Asian tropical summer monsoon is simulated in this paper,and numerical experimental results show that the Indian Peninsula plays a critical role in the establishment process of the Asian tropical summer monsoon.When the CCM3 includes the Indian Peninsula,the model successfully simulates out the course of the Asian tropical summer monsoon,i.e.the South China Sea (SCS) summer monsoon at first bursts in middle May,while the Indian monsoon just establishes until middle June.However when the Indian Peninsula topography is deleted in the model,the Indian and SCS summer monsoons almost simultaneously establish in late May.Numerical results further indicate that in the former experiment the sensible heating of the Indian Peninsula warms the air above and produces evident temperature contrast between the peninsula and its adjacent SCS and Bay of Bengal (BOB).which results in the strengthening and maintenance of the BOB trough in the low-middle layer of the troposphere in the end of spring and early summer and thus the earliest establishment of the Asian tropical summer monsoon in the SCS in middle May.However,the Indian summer monsoon just establishes until middle June when the strong west wind over the Arabian Sea shifts northwards and cancels out the influence of the northwest flow behind the BOB trough.In the latter experiment the effect of Tibetan Plateau only produces a very weak BOB trough,and thus the SCS and Indian summer monsoons almost simultaneously establish.  相似文献   

19.
The latest dataset from the SCS(South China Sea)Monsoon Experiment is used to investigatethe features of abrupt change in some meteorological elements before,during and after the summermonsoon's establishment in 1998 and explore its onset characteristic process.We have arrived at apreliminary conclusion that the 1998 Asian summer monsoon is established first in the SCS as earlyas May 23,which is representative of the earliest indicator of the conversion from a winter into asummer monsoon situation in Asia;the continued retreat eastward of the western Pacificsubtropical high from the SCS region has direct effect on the SCS summer monsoon establishmentbecause the withdrawal favors the release of unstable energy,responsible for the sudden onset ofthe monsoon.Our tentative investigation indicates that the eastward extension of the westerly andrainfall band from the equatorial Indian Ocean into the Indo-China Peninsula and the southwardspreading of an active South-China stationary front,acting as the interaction between mid and lowlatitude systems,are likely to be the characteristic events contributing to the subtropical high'seastward retreating and the summer monsoon's onset over the SCS.  相似文献   

20.
The latest dataset from the SCS(South China Sea) Monsoon Experiment is used to investigate the features of abrupt change in some meteorological elements before,during and after the summer monsoon's establishment in 1998 and explore its onset characteristic process.We have arrived at a preliminary conclusion that the 1998 Asian summer monsoon is established first in the SCS as early as May 23,which is representative of the earliest indicator of the conversion from a winter into a summer monsoon situation in Asia;the continued retreat eastward of the western Pacific subtropical high from the SCS region has direct effect on the SCS summer monsoon establishment because the withdrawal favors the release of unstable energy,responsible for the sudden onset of the monsoon.Our tentative investigation indicates that the eastward extension of the westerly and rainfall band from the equatorial Indian Ocean into the Indo-China Peninsula and the southward spreading of an active South-China stationary front,acting as the interaction between mid and low latitude systems,are likely to be the characteristic events contributing to the subtropical high's eastward retreating and the summer monsoon's onset over the SCS.  相似文献   

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