南海夏季风对华南夏季降水年代际变化的影响

华南夏季降水和南海夏季风都具有准两年的变化特征。研究表明:20世纪70年代以后,华南夏季降水年代际变化主要表现在准两年尺度平均方差的变化上,当准两年方差大时,相应的华南夏季降水多,反之亦然。但是在1976年以前南海夏季风对华南夏季降水的影响并不大,这似乎与两者准两年变化关系的年代际变化有关。南海夏季风和华南夏季降水的准两年变化在1953—1976年是弱的反位相变化关系,相反地,这一时段它们的非准两年变化成分有很强的正相关;在1977—2000年这一阶段,南海夏季风和华南夏季降水的准两年变化具有很强的正相关,但是它们的非准两年变化成分的相关性则很差。分析结果还表明,20世纪70年代大气环流的年代际变异使得华南夏季降水准两年变化在最近20多年成为其年际时间演变的主导成分。

华南夏季大气水汽汇时空变化特征

用1958～2004年NCEP/NCAR再分析资料,分析华南夏季大尺度大气水汽汇的时空变化特征.结果表明：西南地区东部至华南北部地区、华南沿海地区是我国南方夏季水汽汇的2个主要的变异中心区.西南地区东部至华南北部地区夏季水汽汇具有明显的年代际变化特征.华南南部沿岸地区夏季水汽汇则以年际变化为主.西南地区东部至华南北部附近地区以及华南南部沿岸地区水汽汇的强弱异常变化,与东亚上空水汽输送异常而导致上述地区的垂直积分的水汽通量辐合的异常是密切相关：如果向华北或者长江流域的水汽输送增强（减弱）,则华南地区得到的水汽减少（增加）,导致上述地区上空的水汽汇偏弱（偏强）.

华南夏季降水20世纪90年代初的年代际变化及其与南亚高压关系

利用1979—2008年中国160站降水资料、NOAA的CMAP降水资料以及NCEP/NCAR大气再分析资料,应用1978—2008年全球逐月观测海表温度驱动NCAR CAM5.1全球大气环流模式进行数值模拟,探讨了华南夏季降水的年代际变化特征及其与南亚高压的关系。结果表明,华南夏季降水与南亚高压的东伸脊点关系密切,均在20世纪90年代初存在年代际转变。在1993—2008(1979—1992)年期间,南亚高压位置偏西(东),西北太平洋副热带高压位置偏东(西),华南地区则低层辐合(辐散)异常、高层辐散(辐合)异常,产生异常上升(下沉)运动,华南地区降水年代际偏多(少),这也被数值试验结果所验证。

华南夏季大气环流的变异及其与季风降水的关系

利用华南1951～1981年的降水资料，分析了华南夏季风（4～9月）高空环流（500hPa）的配置及其变异对季风降水的影响，得出旱涝年的高空环流特征及其与华南夏季风降水的关系：在欧亚75～20°N之间，沿西北—东南向有明显遥相关；极涡变动与降水密切相关。

华南夏季降水两次年代际转折的水汽输送异常成因初探

本文利用NCEP/NCAR再分析资料和中国2374站日降水资料,通过水汽收支方程分解方法分析了华南夏季降水在1993~2002年时段年代际增多以及2003~2013年时段年代际减少的水汽输送特征及其成因。结果表明:1993~2002年时段(2003~2013年时段),局地环流导致异常下沉(上升)气流,南亚高压偏东(偏西)和西太平洋副热带高压(简称副高)偏西(偏东),菲律宾及副高西南侧水汽输送加强(减弱),华南地区低层出现强的水汽辐合(辐散),导致降水偏多(偏少)。华南地区夏季降水两次年代际变化主要与风速变化引起的水汽输送动力散度项的异常有关,同时还受到与比湿变化引起的水汽输送热力散度项异常、及天气尺度的涡旋引起的水汽输送涡流散度项异常影响。此外,研究发现水汽输送的异常与环流和海温异常均密切相关。

华南地区夏季旱涝特征分析

根据华南地区14个代表站1951—2010年月平均降水量资料,对华南地区夏季(6—8月)降水进行了统计分析。采用单站旱涝Z指数变化和区域旱涝指数对华南地区60年的旱涝进行了分析,并利用小波分析方法,对华南地区夏季降水特征进行研究。结果表明:华南地区夏季降水偏多或偏少时段明显;20世纪90年代以来,偏涝年份明显增多;华南地区夏季降水具有12年、6年和3年左右的周期特征。

华南前汛期持续暴雨环流分型初步研究

采用1961—2010年NCEP/NCAR逐日再分析资料和台站观测降水量资料,按一定标准选取了华南前汛期24个持续暴雨过程;并且按基本判据确定逐年华南夏季风降水开始日期。然后依据南亚高压环流型和相对于该年夏季风降水开始的早晚,将这些暴雨过程划分为夏季风降水前、后南亚高压东部型,夏季风降水后南亚高压带状、西部型共4个类型;其中,夏季风后南亚高压西部型次数最多、平均持续时间最长。所有类型持续暴雨的相同点是:广东东北部附近均为暴雨频率和雨量高值区;暴雨期间华南150 h Pa位势高度增加、500 h Pa位势高度减少;华南处在150 h Pa偏西风急流南侧辐散区中;850 h Pa华南沿海有明显的西南气流,低层辐合在华南东北部最明显;两广沿海为可降水量大值区;华南的整层水汽输送主要呈现西南向。不同点是:夏季风后南亚高压西部型平均雨量较小,夏季风后南亚高压带状型与西部型在印度洋上存在明显的偏东风高空急流;夏季风后南亚高压类型在两广沿海的可降水量数值较大。

论全运会会期的选择

问题的由来举世瞩目的中华人民共和国第五届运动会,原定于1983年9月16日下午在上海江湾体育场举行开幕式。但是,天公不作美。那几天上海秋雨绵绵,有时到大雨程度,致使开幕式一再延期。由此带来了许多意想不到的问题,在政治、经济、体育等方面都产生了一定的影响和损失。那么,应怎样选择全运会的会期呢? 全运会会期的选择与气候关系全运会比赛日期的选择,除考虑政治、经济、体育等方面因素外。

REASONS FOR THE LATE ONSET AND ANOMALOUS SOUTHWARD PERSISTENCE OF THE SOUTH CHINA SEA SUMMER MONSOON IN 2005

Features of atmospheric circulation and thermal structures are discussed using the NCAR/NCEP data to reveal the reasons for the late onset and anomalous southward persistence of the South China Sea Summer Monsoon(SCSSM) in 2005.The results show that three factors are crucial.First,a strong Arabian High overlaps with a high-latitude blocking high and channels strong cold air to southern Asia.Second,the Tibetan Plateau has a bigger snow cover than usual in spring and the melting of snow cools down the surface.Third,the Somali Jet breaks out at a much later date,being not conducive to convection over Indochina.The former two factors restrict atmospheric sensible heating over the Tibetan Plateau and nearby regions while the third one limits latent heating over Indochina.All of the factors slow down atmospheric warming and postpone the onset of SCSSM.Long after the onset of SCSSM,strong cold air over India advances the Southwest Monsoon northward slowly,resulting in weaker convection and latent heating over the Tibetan Plateau and nearby areas.The negative feedback conversely inhibits further northward movement of Southwest Monsoon.

CONNECTION OF THE SOUTH CHINA SEA SUMMER MONSOON TO MARITIME CONTINENT CONVECTION AND ENSO

The relationship between the intensity of the South China Sea summer monsoon （SCSSM） and the Nino3.4 index and anomalous atmospheric circulation patterns associated with a strong and weak SCSSM are investigated using the NCEP/NCAR reanalysis data, Extended Reconstructed Sea Surface Temperature （ERSST） data and Climate Prediction Center Merged Analysis of Precipitation （CMAP） data. The SCSSM is significantly positively correlated with the Nino3.4 index in the succeeding northern autumn and winter. In the strong minus weak SCSSM composite, a positive East Asia-Pacific teleconnection （EAP） pattern and a negative Europe-Asian-Pacific teleconnection （EUP） pattern appear in the 500 hPa height difference field; low-level cross-equatorial flows are strengthened over the Maritime Continent （MC） region; positive （negative） precipitation anomalies occur in the South China Sea and western north Pacific （MC）. A possible mechanism through which SCSSM affects ENSO is proposed. A strong （weak） SCSSM strengthens （weakens） cross-equatorial flows over the MC. The anomalous cross-equatorial flows cool （warm） the SST around the MC through enhanced （reduced） surface latent heat fluxes. The cooling （warming） further leads to suppressed （enhanced） convection over the MC, and causes the anomalous westerly （easterly） in the equatorial western Pacific, which favors the onset of E1 Nino （La Nina） through modulating the positive air-sea feedback process.

NUMERICAL SIMULATION OF SOUTH CHINA SEA MONSOON ONSET BASED ON GRAPES MODEL AND EXPERIMENTS ON INITIAL MODEL FIELDS

The Global and Regional Assimilation and Prediction System (GRAPES), a limited-area regional model, was used to simulate the onset of South China Sea summer monsoon. In view of the relatively insufficient information about the initial field in simulation predictions, the Advanced Microwave Sounding Unit-B (AMSU-B) data from a NOAA satellite were introduced to improve the initial values. By directly using the 3-dimensional variational data assimilation system of GRAPES, two schemes for assimilation tests were designed. In the design, Test 1 (T1) assimilates both sounding and AMSU-B data, and Test 2 (T2) assimilates only the conventional sounding data, before applying the model in simulation forecasts. Comparative experiments showed that the model was very sensitive to initial fields and successful in reproducing the monsoon onset, allocation of high- and low-level wind fields during the pentad of onset, and the northward advancement of the monsoon and monsoon rain bands. The scheme, however, simulated rainfall and the location of the subtropical high with deviations from observations. The simulated location of the subtropical high was more westward and northward and the simulated rainfall for the South China Sea was larger and covered a broader area.

Relationship over southern China between the summer rainfall induced by tropical cyclones and that by monsoon

This study investigates the relationship between tropical cyclone-induced precipitation（P_（TC）） and summer monsoon-induced precipitation（P_（SM）） in southern China（SC） during June-August.The spatial patterns of the first interannual mode are uniform in sign over SC,with positive anomalies for P_（TC） and negative anomalies for P_（SM）.The background of an increase in cyclonic vorticity,an increase in RH,and a decrease in vertical wind shear over the South China Sea（SCS）-western north Pacific（WNP） provides favorable conditions for more TC genesis.The positive equatorial central Pacific SST anomaly and negative North Indian Ocean SST anomaly contribute to the anomalous cyclone over the SCS-WNP,which causes decreasing P_（SM） in SC together with an anomalous anticyclone over eastern China-Japan.By contrast,whilst the spatial patterns of the first interdecadal mode are also uniform in sign over SC,there are positive anomalies for both P_（TC） and P_（SM）.The first interdecadal principal component features significant positive correlation with the number of TCs forming in the SCS.There is a significant increase in P_（TC） and P_（SM） after early 1990 s.A positive tropical Indian Ocean（TIO） SST anomaly persists from the preceding winter to summer.During the preceding winter and spring after the early 1990 s,a positive western Pacific SST anomaly can result in TIO SST warming through vertical circulation.Then,the positive TIO SST anomaly triggers an anomalous WNP anticyclone and contributes to the interdecadal increase in SC P_（SM） in the succeeding summer.The persistent heating source over SC from May to summer related to an earlier onset of the SCS monsoon may strengthen the East Asian subtropical summer monsoon.

A DIAGNOSTIC ANALYSIS OF THE WEAKENING OF WEST PACIFIC SUBTROPICAL ANTICYCLONE DURING THE PERIOD OF SOUTH CHINA SEA SUMMER MONSOON ONSET IN 1998

The onset of South China Sea summer monsoon in 1998 occurred on May 21st. Using the U.S. National Centers for Environmental Prediction reanalysis data, this paper examines the physical process of the weakening of a subtropical anticyclone in West Pacific during the onset period using the Zwack-Okossi vorticity equation. Results show that during the pre-onset period, the positive vorticity advection in front of an upper tropospheric trough was the most dominant physical mechanism for the increase of the cyclonic vorticity on the 850-hPa layer over the South China Sea and its nearby region. The secondary contribution to the increase of the cyclonic vorticity was the warm-air advection. After the onset, the magnitude of the latent-heat warming term rapidly increased and its effect on the increase of the cyclonic vorticity was about the same as the positive-vorticity advection. The adiabatic term and divergence term contributed negatively to the increase of the cyclonic vorticity most of the time. Thus, the positive vorticity advection is the most important physical mechanism for the weakening of the West Pacific subtropical anticyclone over the South China Sea during the onset period.