The South China Sea Monsoon Experiment(SCSMEX) Implementation Plan

ＴｈｅＳｏｕｔｈＣｈｉｎａＳｅａＭｏｎｓｏｏｎＥｘｐｅｒｉｍｅｎｔ（ＳＣＳＭＥＸ）ＩｍｐｌｅｍｅｎｔａｔｉｏｎＰｌａｎＤｉｎｇＹｉｈｕｉ（丁一汇），ＣｈａｏＱｉｎｇｃｈｅｎ（巢清尘），ＺｈａｎｇＹａｎ（张雁），ＧａｎＺｉｊｕｎ（甘子钧）①ａｎｄＺｈａ...     

''98南海季风(SCSMEX)和高原科学试验(TIPEX)边界层

使用1998年南海季风(SCSMEX)试验和青藏高原科学试验(TIPEX)的边界层资料对Ekman特征进行了动力学研究。得到如下结果：(1)在青藏高原和南海及其周围区域有类似的Ekman动力学特征。(2)比较研究表明，边界层厚度在青藏高原约为2250m且考虑到它的摆动特性，其厚度可在2250-2750m之间。在热带西南太平洋边界层厚度约为2000m，其厚度摆动较小，在平原地区边界层厚度较低。（3）由于高原和热带海域海拔高度的不同，尽管在高原和热带海区有着几乎同样的边界层厚度，但边界层对大气的影响是相当不同的。考虑到海拔高度的影响，在这两个地区摩擦力作用的空间部位的高度有相当大的差别。(4)这两个区域的湍流摩擦的垂直结构差异较大。使用’98SCSMEX和TIPEX边界层资料计算结果表明，即使在低层，平均湍流粘性力在高原上是热带海域的2．3倍。     

南海季风区冰相相变潜热对中尺度对流云和降水影响作用的数值模拟研究

利用可分辨云模式及中国南海北部试验区加密探空的平均水平风场、位温场和水汽场模拟分析了1998年5月15日至6月11日中国南海北部地区中尺度对流系统(Mesoscal Convective System,简称MCS)中冰相相变潜热对云和降水、辐射传输以及大尺度环境场的影响作用。研究表明,冰相相变潜热总体上不会引起明显的大气辐射通量的变化,但会引起较明显的下垫面热通量的变化。凝华潜热释放显著地增加了大气稳定度,造成对流和下垫面热通量的减弱,从而导致地面降水减小10.11%。碰冻潜热释放也使得大气稳定度增加,不利于中尺度对流系统对流的发展,区域累积降水量减小2.2%。融化潜热的冷却效应,使得融化层以下的大气降温,从而增加了低层大气的不稳定性,有利于海面热通量的输送,导致MCS降水增加4.1%。因此,冰相相变潜热对降水的影响主要是通过影响大气环境稳定,进而影响洋面感热通量和潜热通量的垂直输送和对流的发展,导致区域降水改变。     

南海季风爆发期间中尺度对流云带演变特征与持续性加强的机理研究

南海季风爆发与随后爆发的东亚季风,与夏季东亚地区旱涝关系密切,而相伴的南海对流活动与季风爆发的维持和发展存在何种相互关系,是需要探究的.为此,利用热带测雨卫星(Tropical Rainfall Measuring Mission,TRMM)的雷达(Precipitation Radar,PR)、微波成像仪(TRMM ...     

南海季风试验与东亚夏季风

南海季风试验是一次国际性大气与海洋的联合试验 ,旨在更好地了解南海季风的爆发、维持与变化 ,以改进东亚和东南亚地区的季风预报。 1998年 5～ 8月进行的外场试验取得了圆满成功 ,获得了大量气象与海洋资料。不少国家对这些资料进行四维资料同化 ,并改进数值模拟和预报 ;同时也为东亚与南海地区季风的研究提供了必要的资料集。文中总结了中国科学家在这方面的主要研究成果 ,共包括 6个方面 :(1)南海夏季风的爆发过程与机理 ;(2 )南海季风爆发过程中对流与中尺度系统的发展及其与大尺度环流的相互作用 ;(3)低频振荡与遥相关作用 ;(4 )南海海 气通量的测量及其与季风活动的关系 ;(5 )夏季风时期南海海洋的热力结构、环流和中尺度涡旋及其与ENSO事件的关系 ;(6 )南海与东亚季风的数值模拟。     

South China Sea Monsoon Experiment （SCSMEX） and the East Asian Monsoon

The SCSMEX is a joint atmospheric and oceanic experiment by international efforts, aiming at studying the onset, maintenance, and variability of the South China Sea (SCS) summer monsoon, thus improving the monsoon prediction in Southeast and East Asian regions. The field experiment carried out in May-August 1998 was fully successful, with a large amount of meteorological and oceanographic data acquired that have been used in four dimensional data assimilations by several countries, in order to improve their numerical simulations and prediction. These datasets are also widely used in the follow-up SCS and East Asian monsoon study. The present paper has summarized the main research results obtained by Chinese meteorologists which cover six aspects: (1) onset processes and mechanism of the SCS summer monsoon; (2) development of convection and mesoscale convective systems (MCSs) during the onset phase and their interaction with large-scale circulation; (3) low-frequency oscillation and teleconnection effect; (4) measurements of surface fluxes over the SCS and their relationship with the monsoon activity; (5) oceanic thermodynamic structures, circulation, and mesoscale eddies in the SCS during the summer monsoon and their relationship with ENSO events; and (6) numerical simulations of the SCS and East Asian monsoon.     

Low Salinity, Cool-Core Cyclonic Eddy Detected Northwest of Luzon during the South China Sea Monsoon Experiment (SCSMEX) in July 1998

To detect eddies, intensive surveys of the northeast South China Sea (SCS) (114°30′–121°30′ E, 17°–22°N) were conducted in July 1998 during the international SCS Monsoon Experiment (SCSMEX), the U.S. Navy using Airborne Expendable Bathythermograph and Conductivity-Temperature-Depth sensors (AXBT/AXCTD), and the Chinese Academy of Sciences using Acoustic Doppler Current Profilers (ADCP). The hydrographic survey included 307 AXBT and 9 AXCTD stations, distributed uniformly throughout the survey area. The ADCP survey had two sections. The velocity field inverted from the AXBT/AXCTD data and analyzed from the ADCP data confirm the existence of a low salinity, cool-core cyclonic eddy located northwest of Luzon Island (i.e., the Northwest Luzon Eddy). The radius of this eddy is approximately 150 km. The horizontal temperature gradient of the eddy increases with depth from the surface to 100 m and then decreases with depth below 100 m. The cool core was evident from the surface to 300 m depth, being 1°–2°C cooler inside the eddy than outside. The tangential velocity of the eddy is around 30–40 cm/s above 50 m and decreases with depth. At 300 m depth, it becomes less than 5 cm/s. This revised version was published online in August 2006 with corrections to the Cover Date.