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1.
The heavy rainfall in the summer of 1998 over China has been simulated with the NCC Regional Climate Model(RegCM_NCC).It was successful for RegCM_NCC to reproduce the location and seasonal shift of the seasonal rain belt in the summer of 1998 over China.The rainy season in the summer of 1998 over China can be divided into 7 episodes,including the pre-summer rainy season in South China.the Meiyu onset over the Yangtze-Huaihe River Basin,short appearance of North China rain season and the retreat of seasonal rain belt,the second Meiyu season over the Yangtze River Valley,the rainy period over the Yellow and Huaihe River Valley and the seasonal retreat of rain belt over North China.The shortcoming of the RegCM_NCC is over-estimation of precipitation amounts.The regions with large latent heat flux,upper soil moisture and total runoff are located in the rainy area and move with the simulated rain belt during the different episodes.On the contrary,the regions with small sensible heat flux are located in the simulated rainy area and move with the simulated rain belt during the different episodes. 相似文献
2.
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
3.
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
4.
中国地区降水持续性的季节变化特征 总被引:6,自引:1,他引:5
本文利用我国588个气象站1969-2008年逐12小时的降水资料,分析了中国地区降水持续性的空间分布特征及其季节演变规律。分析结果表明,35°N以南,西部和东部年平均的降水平均持续时间较长,中部略短;35°N以北,西北和内蒙西部最短,东北地区北部略长。将降水事件按持续时间分类自南向北,东南地区、江淮和黄淮地区、东北和华北北部地区短时降水(持续一个时次,12小时)的降水量和降水频率占全年总降水的比例逐渐增加,持续性降水(持续3个时次及以上)的比例减少。降水平均持续时间随季节的变化基本能反映出江南春雨、江淮梅雨、东北和华北夏季雨季、关中盆地和汉水谷地的秋雨以及青藏高原地区和西南地区夏季雨季。同时,东南地区秋冬季节、江淮和黄淮地区10月上旬和西南地区10月下旬存在降水平均持续时间的峰值,与降水量的变化不一致,是由持续性降水频率的增加和短时降水频率的减少造成的。此外,东部三个区域降水平均持续时间的夏季季节内变化对应了季风雨带的“北跳和南撤”过程。 相似文献
5.
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
6.
Seasonal variability regarding the nature of precipitation and the activity of cumulus convection during the 1991 Meiyu season of Changjiang-Huaihe River Basin(Jianghuai)has been investigated by calculating apparent heat source/apparent moisture sink and analyzing TBB(cloud-top blackody radiation temperature)data.It is found that three periods of strong ascending motion during the Meiyu season lead to three episodes of heavy rain,and the latent heat due to the precipitation is of the sole heat source of the atmosphere.The nature of precipitation shows distinct seasonal variability,from frontal precipitation of the first episode to the extremely strong convective precipitation of the third episode.TBB field of East Asia may well reflect not only the intensity of convection and rainfall,but also the movement of rain belt and convection belt.In the whole Meiyu season.convection belt mainly stays in Jianghuai.but may shift within the domain of East Asia.Its locating in Jianghuai or not determines the maintenance or break of Meiyu.In the third episode,the narrow convection belt over Jianghuai is mainly caused by southwest monsoon which takes moist and convective atmosphere from tropical ocean. 相似文献
7.
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
8.
9.
东亚夏季风次季节(10~90 d)变化是中国夏季持续性强降水、高温热浪等高影响天气事件的重要环流载体,处于天气预报上限和气候季节预测下限之间的预报过渡区。研究表明:东亚夏季风次季节变化是东亚夏季风的固有物理特征,它和季节进程之间的时间锁相关系是东亚夏季风次季节变化潜在可预报性的重要来源。东亚夏季风次季节变化与Madden-Julian振荡(MJO)存在显著差异,试图通过MJO来预测东亚夏季风次季节变化的不确定性较大。东亚夏季风次季节预测的另一重要来源是下垫面外强迫,包括欧亚大陆春季积雪、中国东部春季土壤湿度和厄尔尼诺-南方涛动(ENSO)事件。此外,去趋势偏-交叉相关分析统计方法能够分析东亚夏季风多因子和多时间尺度问题。目前,亟需解决的科学问题包括:东亚夏季风次季节模态的客观定量描述、造成东亚夏季风次季节模态年际变化的关键物理过程、不同外强迫因子对东亚夏季风次季节模态的共同影响。 相似文献
10.
A nested regional climate model has been experimentally used in the seasonal prediction at the China National Climate Center (NCC) since 2001. The NCC/IAP (Institute of Atmospheric Physics) T63 coupled GCM (CGCM) provides the boundary and initial conditions for driving the regional climate model (RegCM NCC). The latter has a 60-km horizontal resolution and improved physical parameterization schemes including the mass flux cumulus parameterization scheme, the turbulent kinetic energy closure scheme (TKE) and an improved land process model (LPM). The large-scale terrain features such as the Tibetan Plateau are included in the larger domain to produce the topographic forcing on the rain-producing systems. A sensitivity study of the East Asian climate with regard to the above physical processes has been presented in the first part of the present paper. This is the second part, as a continuation of Part I. In order to verify the performance of the nested regional climate model, a ten-year simulation driven by NCEP reanalysis datasets has been made to explore the performance of the East Asian climate simulation and to identify the model’s systematic errors. At the same time, comparative simulation experiments for 5 years between the RegCM2 and RegCM NCC have been done to further understand their differences in simulation performance. Also, a ten-year hindcast (1991–2000) for summer (June–August), the rainy season in China, has been undertaken. The preliminary results have shown that the RegCM NCC is capable of predicting the major seasonal rain belts. The best predicted regions with high anomaly correlation coefficient (ACC) are located in the eastern part of West China, in Northeast China and in North China, where the CGCM has maximum prediction skill as well. This fact may reflect the importance of the largescale forcing. One significant improvement of the prediction derived from RegCM NCC is the increase of ACC in the Yangtze River valley where the CGCM has a very low, even a negative, ACC. The reason behind this improvement is likely to be related to the more realistic representation of the large-scale terrain features of the Tibetan Plateau. Presumably, many rain-producing systems may be generated over or near the Tibetan Plateau and may then move eastward along the Yangtze River basin steered by upper-level westerly airflow, thus leading to enhancement of rainfalls in the mid and lower basins of the Yangtze River. The real-time experimental predictions for summer in 2001, 2002, 2003 and 2004 by using this nested RegCM NCC were made. The results are basically reasonable compared with the observations. 相似文献
11.
12.
NATURE OF PRECIPITATION AND ACTIVITY OF CUMULUS CONVECTION DURING THE 1991 MEIYU SEASON OF CHANGJIANG-HUAIHE RIVER BASIN 下载免费PDF全文
下载免费PDF全文 Seasonal variability regarding the nature of precipitation and the activity of cumulus convectionduring the 1991 Meiyu season of Changjiang-Huaihe River Basin(Jianghuai)has been investigatedby calculating apparent heat source/apparent moisture sink and analyzing TBB(cloud-topblackbody radiation temperature)data.It is found that three periods of strong ascending motionduring the Meiyu season lead to three episodes of heavy rain,and the latent heat due to theprecipitation is of the sole heat source of the atmosphere.The nature of precipitation showsdistinct seasonal variability,from frontal precipitation of the first episode to the extremely strongconvective precipitation of the third episode.TBB field of East Asia may well reflect not only theintensity of convection and rainfall,but also the movement of rain belt and convection belt.In thewhole Meiyu season.convection belt mainly stays in Jianghuai.but may shift within the domain ofEast Asia.Its locating in Jianghuai or not determines the maintenance or break of Meiyu.In thethird episode,the narrow convection belt over Jianghuai is mainly caused by southwest monsoonwhich takes moist and convective atmosphere from tropical ocean. 相似文献
13.
A nested regional climate model has been experimentally used in the seasonal prediction at the China National Climate Center (NCC) since 2001. The NCC/IAP (Institute of Atmospheric Physics) T63coupled GCM (CGCM) provides the boundary and initial conditions for driving the regional climate model (RegCM_NCC). The latter has a 60-km horizontal resolution and improved physical pararneterization schemes including the mass flux cumulus parameterization scheme, the turbulent kinetic energy closure scheme (TKE) and an improved land process model (LPM). The large-scale terrain features such as the Tibetan Plateau are included in the larger domain to produce the topographic forcing on the rain-producing systems. A sensitivity study of the East Asian climate with regard to the above physical processes has been presented in the first part of the present paper. This is the second part, as a continuation of Part Ⅰ.In order to verify the performance of the nested regional climate model, a ten-year simulation driven by NCEP reanalysis datasets has been made to explore the performance of the East Asian climate simulation and to identify the model's systematic errors. At the same time, comparative simulation experiments for 5 years between the RegCM2 and RegCM_NCC have been done to further understand their differences in simulation performance. Also, a ten-year hindcast (1991-2000) for summer (June-August), the rainy season in China, has been undertaken. The preliminary results have shown that the RegCM_NCC is capable of predicting the major seasonal rain belts. The best predicted regions with high anomaly correlation coefficient (ACC) are located in the eastern part of West China, in Northeast China and in North China,where the CGCM has maximum prediction skill as well. This fact may reflect the importance of the largescale forcing. One significant improvement of the prediction derived from RegCM_NCC is the increase of ACC in the Yangtze River valley where the CGCM has a very low, even a negative, ACC. The reason behind this improvement is likely to be related to the more realistic representation of the large-scale terrain features of the Tibetan Plateau. Presumably, many rain-producing systems may be generated over or near the Tibetan Plateau and may then move eastward along the Yangtze River basin steered by upper-level westerly airflow, thus leading to enhancement of rainfalls in the mid and lower basins of the Yangtze River.The real-time experimental predictions for summer in 2001, 2002, 2003 and 2004 by using this nested RegCM_NCC were made. The results are basically reasonable compared with the observations. 相似文献
14.
汛期内我国中东部地区的雨季是东亚夏季风推进过程中的重要产物,主要包括华南前汛期、梅雨、华北雨季和华西秋雨等,各地雨季决定了我国中东部地区汛期的旱涝布局和旱涝演变,是我国汛期预测和服务的重点。该文回顾了4个雨季特征及影响因子方面的研究进展,在此基础上梳理物理概念预测模型。研究显示:海温异常是影响各区域雨季的重要先兆信号,但不同雨季的年际和年代际变化特征不同,海温作为外强迫信号的影响程度和时空形式也有差异。利用热带太平洋东西海温差指标能更好地解释华南前汛期降水的年际变化。而与梅雨的年际变化分量相关联的海温关键区主要分布于热带,与年代际或多年代际变化分量相联系的海温关键区则来自中高纬度。华北雨季降水的强弱不仅与ENSO循环的位相有关,更多受到ENSO演变速率的影响。而影响华西秋雨的海温关键区随着年代际背景的变化发生了改变,需要重新诊断和建模。 相似文献
15.
1991年江淮特大暴雨的降水性质与对流活动 总被引:11,自引:3,他引:11
从计算大尺度热源和分析TBB资料两个方面,阐述了1991年江淮梅雨期间降水性质与对流活动的季节性演变特征。结果表明:梅雨期间江淮上空3个强上升运动时段分别形成了3场暴雨,由暴雨释放的热量使江淮大气出现了3个时段的强加热;3场暴雨的降水性质呈显著的季节性演变,由第1场暴雨以锋面性降水为主发展到第3场暴雨异常强的对流性降水。文中详细分析了热源和水汽汇的时空分布特征,并从大气运动场和热力结构讨论了盛夏强对流降水期间积云对流以涡动形式对热量和水汽的强铅直输送作用。江淮地区TBB值能很好地反映降水状况,雨期一致地对应于TBB低于250K的时段。梅雨中后期东亚地区对流活动季节性地增强,带状对流区(特别是TBB高负距平区)与雨带位置相符。对流带位置及对流活动强弱与西南暖湿气流活动密切相关,它很好地表征了东亚地区的低空急流(给积云输送热带对流大气)。梅雨期间对流带主要出现在江淮流域,但可在东亚范围内飘移,它落在江淮与否则决定了江淮暴雨的维持与中断 相似文献
16.
据1991年特大洪涝过程的物理分析试论江淮梅雨预测 总被引:8,自引:0,他引:8
本文以1991年江淮梅雨为个例,通过对特大洪涝形成过程的物理分析,就梅雨预测问题提出了一些认识。分析表明,1991年江淮流域较长梅雨期内所发生的3场大暴雨是很有代表性的,它们是大气环流季节转变不同进程中的产物,因而具有不同的环流背景和降水性质,且在洪涝的形成中起着不同的作用。据此,我们提出了江淮梅雨的3个模型,指出应在由春夏之交到盛夏这个较长时期内分阶段地考虑梅雨预测。另外还指出,确定雨带的落区,不但应强调副高和东南季风活动对雨带南北进退的作用,而且也要注意西南季风的活动会导致雨带东西向的摆动。最后,就旱涝形成物理过程的诊断研究在旱涝模式预测方法中的意义作了讨论 相似文献
17.
1. Introduction As an important way to study the global climate change, because of its low resolution, GCM (general circulation model) shows obvious deficiency and uncer- tainty in capturing some regional features when used in the regional climate study, and the uncertainty is even serious in regional climate simulation over East Asia (Ding et al., 2000; Zhao and Luo, 1998; Qian et al., 1999). The high-resolution regional climate model (RegCM) developed in the 1980s can provide better simu… 相似文献
18.
本文利用1961—2016年中国汛期逐候降水的旋转经验正交函数分解(Rotated Empirical Orthogonal Function, REOF)方法对中国汛期雨带进行客观划分。根据REOF模态空间分布以及主成分的气候态平均确定了中国汛期6个主要雨带的落区和时间,并揭示了各雨带气候态环流特征。江南春雨雨带主要发生在长江以南地区,对应时间为26—27候;南方雨季的雨带落区主要在两广至福建地区,对应时间为33—34候;江南及中下游梅雨主要落区在长江以南和长江中下游流域,对应时间分别为34—35和36—37候;华北东北雨季落区在华北至东北地区,发生时间为41—42候;华西秋雨落区在秦岭及其周围地区,对应发生时间为49—52候。在雨带划分的基础上,进一步揭示了各个雨带典型的对流层中高低气候态环流特征。可为客观定义汛期雨带及各雨带气候预测提供参考。 相似文献
19.
中国雨季的气候学特征 总被引:43,自引:12,他引:31
利用中国740站气候平均逐候降雨量对中国的主雨季进行定义,并对雨季(包括主雨季,春雨和秋雨)的气候学特征进行了讨论。结果表明:全国主雨季最早爆发于华南中部,最晚结束于华西地区。主雨季能持续4到14候不等,雨量占年总降水的30%~60%。主雨季在中国东部为季风雨季,自南向北推进;在西部受西风带影响,北方略早于南方, 且局地性强。中国雨季具有明显的区域性和阶段性特征。中国气候的夏季降水时间序列主要反映了季节循环特征, 但气候季节内振荡(CISO)对东部雨季的持续和推进具有明显的调制作用,其中长江中下游及其以南地区以30~60天周期为主。 相似文献
20.
Seasonal Transition of Summer Rainy Season over Indochina and Adjacent Monsoon Region 总被引:10,自引:0,他引:10
Jun MatsumotoDepartment of Geography University of Tokyo -- Hongo Bunkyo-ku Tokyo Japan 《大气科学进展》1997,(2)
SeasonalTransitionofSummerRainySeasonoverIndochinaandAdjacentMonsoonRegionJunMatsumotoDepartmentofGeography,UniversityofTokyo... 相似文献