吕宋海峡黑潮脱落涡旋的特征分析

涡旋脱落在西太平洋和南海的海水属性交换中起到重要作用。为研究吕宋海峡附近海域由黑潮脱落并进入南海的涡旋特征,本文采用1993—2014年法国空间局(AVISO)多卫星融合海面高度距平(SLA)和绝对动力地形(ADT)全球网格化延时数据,美国国家海洋数据中心(NODC)的WOA13年平均温盐剖面气候数据,以及1993—2010年SODA2.2.4月平均海洋同化数据集,并分析了黑潮脱落涡旋与大尺度环流的关系。结果表明:(1)暖涡脱落数量远多于冷涡数量,且脱落的冷涡绝大部分在黑潮西侧边缘生成,而脱落的暖涡则大部分在黑潮控制区生成。(2)冷涡、暖涡脱落时的平均半径、平均振幅相近,但是冷涡的平均生命、平均迁移距离约为暖涡的一半。(3)冷涡不是每年都有脱落,主要在冬季脱落;暖涡则每年均有脱落,主要发生在秋季。(4)脱落涡旋数量与脱落时的黑潮路径类型相关。(5)脱落涡旋的平均西行速度为5.8cm/s,与斜压第一模态长Rossby波波速及大尺度环流的西向平流流速之和相近。     

基于大涡模拟耦合模式的小尺度海气相互作用研究

大气和海洋是影响地球气候系统的两个重要因素,它们之间的相互作用是海洋和大气研究的重要课题,海气耦合模式则是研究海气相互作用的重要工具,而海气耦合模式重点考虑的参数是海气通量。针对传统的大尺度海气耦合模式缺少湍流尺度分析的问题,本文使用并行大涡模拟海气耦合模式（The Parallelized Large-Eddy Simulation Model,PALM）,在小尺度上探究风速对海气通量及湍流动能收支（Turbulence Kinetic Energy Budget,TKE Budget）的影响,设置了5、10和15m/s三种地转风速度对大气边界层（Atmospheric Boundary Layer,ABL）和海洋混合层（Oceanic Mixed Layer,OML）进行海气耦合模拟。研究表明：海气通量的分布与风速大小密切相关,风速越大,净热通量和浮力通量相对越大,由于温度上升导致海水蒸发加剧,使得大气的淡水通量增大;海洋湍流动能收支各项在近海面处受风速影响较大,且随着深度加深而逐渐减弱。本研究初步展示了小尺度海气耦合模式在海气通量研究中的应用,对进行小尺度海气相互作用研究具有一定的意义。     

基于海洋模式数据的吕宋海峡输运量和菲律宾黑潮流量关系的分析

利用全球涡分辨率海洋环流模式OFES的60年(1950—2009)输出资料,用流速资料计算了吕宋岛东侧18°N断面黑潮上游流量(Kuroshio Transport,KT)和120.5°E断面吕宋海峡输运量(Luzon Strait Transport,LST)。研究表明,KT和LST存在四种情况,即:(1)KT大LST小、(2)KT大LST大、(3)KT小LST小和(4)KT小LST大,分别占其总数的34%、11%、13%、42%。合成分析证实:一般情况下,KT大对应黑潮跨越吕宋海峡流态,此时LST较小;KT小时,地转β效应迫使黑潮向西入侵吕宋海峡,此时LST大。然而,吕宋岛东侧和台湾东南沿岸的涡旋常削弱黑潮在吕宋海峡处流量,造成KT大时黑潮亦入侵吕宋海峡,从而出现KT大LST大的情形;太平洋一侧的异常高海表高度诱发吕宋海峡处强地转流,造成KT虽小而黑潮在吕宋海峡处仍是跨越流态,因而LST小。结果表明,LST不仅受KT影响,亦受局地涡旋和海表高度的重要控制。     

台湾以东中尺度涡对黑潮入侵东海路径的影响

利用AVISO数据集的卫星高度计资料,分析了中国台湾以东中尺度涡的时空特征,通过具体的中尺度涡实例探讨了其对台湾以东黑潮路径的影响。研究表明气旋式中尺度涡在春夏季节的数目要少于反气旋式中尺度涡,在秋冬季节气旋式涡旋个数则多于反气旋涡;并且台东以东区域涡旋传播存在多种路径,涡旋的存在对台湾东北部黑潮入侵东海的路径具有重大影响,特别是2004年夏季台湾以东区域存在多个涡旋,相应的吕宋海峡黑潮主轴向东偏移明显,台湾东北黑潮入侵东海的路径发生了显著变化。     

涡分辨率模式模拟的南海中尺度涡旋

Mesoscale eddies(MEs) in the South China Sea(SCS) simulated by a quasi-global eddy-resolving ocean general circulation model are evaluated against satellite data during 1993–2007. The modeled ocean data show more activity than shown by the satellite data and reproduces more eddies in the SCS. A total of 345(428) cyclonic eddies(CEs) and 330(371) anti-cyclonic eddies(AEs) generated for satellite(model) data are identified during the study period, showing increase of ~24% and ~12% for the model data, respectively. Compared with eddies in satellite, the simulated eddies tend to have smaller radii, larger amplitudes, a slightly longer lifetime, faster movement and rotation speed, a slightly larger nonlinear properties(U/c) in the model. However, the spatial distribution of generated eddies appears to be inhomogeneous, with more CEs in the northern part of SCS and fewer AEs in the southern part. This is attributed to the exaggerated Kuroshio intrusion in the model because the small islands in the Luzon Strait are still not well resolved although the horizontal resolution reaches(1/10)°. The seasonal variability in the number and the amplitude of eddies generated is also investigated.     

WRF_ROMS-1.2中尺度海气耦合模式简介

本文介绍了WRF_ROMS-1.2中尺度海气耦合模式的研发背景、子模式、耦合技术,并依照模块功能介绍了该耦合模式中各子模块的主要作用。WRF_ROMS-1.2采用的MCT(ModelCoupling Toolkit)耦合器技术及消息传递的并行计算方式,均为当前多模式耦合的先进技术,很大程度上提高了模式的可扩展性和计算效率,为耦合模式的建立以及中尺度海气相互作用(尤其是热带气旋期间的海气相互作用)的研究、模拟和预报提供建设性参考。     

一个区域耦合海气模式及其实验

本文研制了一个区域的简单耦合海气模式,并用来模拟热带太平洋ENSO循环.模式由一层大气模式和一层海洋模式构成.大气模式由运动方程和热力方程组成;海洋模式由运动方程、连续方程和海温方程组成.非绝热加热与风应力构成海气间耦合媒介项,其中大气对海洋的影响以风应力为主,海洋对大气的影响以非绝热加热为主.在理论分析和数值实验的基础上,成功地实现了简单海气耦合模式的正常运转,并且应于对1982-1983年埃尔尼诺现象的数值模拟.对该事件从发展到衰弱的全过程,特别是中期与成熟期获得了良好的模拟效果,显示出本模式的模拟能力,也验证了热带太平洋区域耦合海气作用对ENSO循环的重大贡献.     

POAMA海气耦合模式对2003和2004年南海夏季风预报能力的评估

运用澳大利亚大气海洋耦合预报模式（Predictive Ocean Atmosphere Model for Australia,POAMA）的输出结果,采用泰勒图与分类统计分析方法,评估了该模式对2003和2004年南海夏季风的爆发和演变进行实时预报的能力。通过对泰勒图的分析发现,随着预报初始时间越来越接近实际的季风爆发时间,模式预报南海夏季风爆发和演变的能力越来越强。当提前1-30d预报南海夏季风时,模式能够很好地预报风场、射出长波辐射OLR（Outgoing Longwave Radiation）和降水场的空间分布,其中对风场的预报最好。通过对季风爆发指数和分类统计的分析,定量分析了模式预报南海夏季风爆发的能力,结果表明该模式对南海夏季风爆发时间有一定的预报能力,其最大预报时限可以提前10-15d左右,这与目前中期预报的上限（2周）是一致的。     

涡分辨率的南海区域海洋环流模式构建技术研究

针对复杂海洋中尺度现象模拟仿真的技术难题,利用区域海洋环流模式ROMS,通过模式的网格构建、地形处理以及模式的初始场和强迫场处理技术,构建出一套涡分辨率南海区域海洋环流模式。通过模式模拟结果与卫星遥感实测资料等对比,发现该模式能够较好地模拟出南海涡旋及其引发的海温异常等海洋中小尺度过程,说明该模式可作为研究复杂海洋中尺度现象影响海军武器装备效能的环境数值仿真手段。     

黑潮在吕宋海峡的形变及动力机制

根据１９９０年以来对吕宋海峡和中国南海（ＳＣＳ）北部的ＷＯＣＥ水文资料和其它海洋调查资料的分析，以及对同一海区的卫星遥测海表温度（ＳＳＴ）的资料处理，推断在吕宋海峡常年存在黑潮路径弯曲，西折进入ＳＣＳ并又流出ＳＣＳ的现象，作者将黑潮的这种变形称为“黑潮流套”。黑潮变形进入ＳＣＳ的位置在冬季位于海峡中部、南部附近，范围较大；在夏季略向北移，较集中于海峡中部，范围较小。作者认为，黑潮流套现象可用位涡守恒理论作定性的解释：当黑潮在吕宋海峡失去西边界支持后，其流轴以西贴近西边界的一部分流体，因具有较大的相对正涡度，会脱离黑潮主体在南海东北部形成反时针旋转或顺时针旋转的环流，而黑潮主体会以顺时针旋转的形式在海峡以西的海域出现。整个黑潮以弯曲、扩展的形式在海峡处产生形变，在海峡东侧出现反气旋涡旋的倾向。吕宋海峡黑潮流套及南海北部的诱生环流之流型，会因黑潮本身以及副热带环流整体的变化而变化，也与海峡的宽度有关。总之，吕宋海峡黑潮流套的形成是由当地特殊的地形条件和地转β效应这些内部机制决定的，它的常年存在有其必然性     

Hydrological analysis of Kuroshio water intrusion into the South China Sea

IN~crIONInvestigation of physical oceanography in the sleuth China Sea can be traced back tO the early17th century. America, England, Japan and Russia all carried out investigations in the sea. Butthe survey areas were limited and the data were scrappy. After entering this century big progresshas been achieved in the investigation of the sea both in the scale of survey and the depth ofstudy. So far the papers such as "Wind and drift currents in the mouth China Sea" (Dale, 1956)and "Phys…     

黑潮入侵优化对南海北部中尺度涡旋模拟的影响

基于高分辨率海洋环流模式,通过比较吕宋海峡处地形优化后的黑潮入侵形态和强度不同的试验,我们研究了黑潮入侵优化后对南海中尺度涡模拟的影响。我们发现黑潮入侵的减弱导致了涡旋活动的减弱,这使得模式结果与观测结果更为相近。在这种情况下,模式模拟的吕宋海峡西部及北部陆坡区域的涡动动能明显减弱。模式涡动动能的减弱与模式反气旋式涡数量的减少和气旋式涡强度的减弱有关。涡动动能收支的分析进一步表明,黑潮入侵的优化将通过改变水平速度切变和温跃层斜率来改变涡动动能,而这两个参数分别与正压和斜压不稳定性有关。前者在模式涡动动能减弱中起着更为重要的作用,而黑潮入侵导致的涡动动能的水平输送对吕宋海峡西部区域的能量收支同样起着重要的作用。     

Interannual variability of the Kuroshio intrusion in the South China Sea

The interannual variability of intrusions of the Kuroshio into the South China Sea (SCS) is investigated using satellite remote sensing data supported by in-situ measurements. The mesoscale circulation of the SCS is predominantly wind-forced by the northeast winter and southwest summer monsoons. Although the region has been studied extensively, considerable uncertainty remains about the annual and interannual mesoscale nature of the circulation. The frequency and characteristics of Kuroshio intrusions and their effect on circulation patterns in the northeast SCS are also not well understood. Satellite observations of Sea Surface Temperature (SST) from the Tropical Rainfall Measuring Mission (TRMM) and the Advanced Very High Resolution Radiometer (AVHRR) and Sea Surface Height Anomalies (SSHA) from TOPEX/ Poseidon for the period 1997–2005 are used here to analyze the annual and interannual variability in Kuroshio intrusions and their effects on the region. Analysis of SST and SSHA shows the formation and characteristics of intrusions vary considerably each year. Typically, the intrusion occurs in the central region of Luzon Strait and results in an anticyclonic circulation in the northeastern SCS. However, in some years, the intrusion is located in the northern portion of Luzon Strait and a cyclonic intrusion results. Wind stress and wind stress curl derived from the National Aeronautics and Space Administration (NASA) QuikSCAT satellite scatterometer are used to evaluate the relationship between wind stress or wind stress curl and the presence of winter Kuroshio intrusions into the SCS.     

黑潮入侵对南海东北部浮游植物群落结构的影响

To further understand the effect of Kuroshio intrusion on phytoplankton community structure in the northeastern South China Sea(NSCS, 14°–23°N, 114°–124°E), one targeted cruise was carried out from July to August, 2017. A total of 79 genera and 287 species were identified, mainly including Bacillariophyta(129 species), Pyrrophyta(150 species), Cyanophyta(4 species), Chrysophyta(3 species) and Haptophyta(1 species). The average abundance of phytoplankton was 2.14×10~3 cells/L, and Cyanobacterium was dominant species accounting for 86.84% of total phytoplankton abundance. The abundance and distribution of dominant Cyanobacterium were obviously various along the flow of the Kuroshio, indicating the Cyanobacterium was profoundly influenced by the physical process of the Kuroshio. Therefore, Cyanobacterium could be used to indicate the influence of Kuroshio intrusion. In addition, the key controlling factors of the phytoplankton community were nitrogen, silicate, phosphate and temperature, according to Canonical Correspondence Analysis. However, the variability of these chemical parameters in the study water was similarly induced by the physical process of circulations. Based on the cluster analysis, the similarity of phytoplankton community is surprisingly divided by the regional influence of the Kuroshio intrusion, which indicated Kuroshio intrusion regulates phytoplankton community in the NSCS.     

吕宋海峡及南海北部海域的水团分析

根据1992年3月和1994年9月台湾海峡两岸科学家对南海北部两次协同调查的CTD资料以及由此计算的重力势资料,对吕宋海峡及南海北部400m以上海水的温盐性质进行分析。结果发现,调查海区基本可划分为两种水团,即黑潮水和南海水。黑潮水主要从吕宋海峡中部和北部进入南海,侵入的黑潮水向西北方向扩展,受到台湾海峡海底地形的阻挡而大部分集中于台湾西南海域,向西的范围基本不超过119°E。虽然两次观测所处的季节不同（分别为春初和夏末）,但黑潮入侵南海的差异并不明显。另外,在二次调查的部分层次上,南海北部陆坡边缘都发现有一团水平尺度约百公里的黑潮性质水。配合重力势的水平分布形式,可以用地转流场的结构解释水团分析的结果。     

Kuroshio intrusion into the South China Sea with an anticyclonic eddy: evidence from underwater glider observation

In this study, high-resolution temperature and salinity data obtained from three Sea-Wing underwater gliders were used together with satellite altimeter data to track the vertical thermohaline structure of an anticyclonic eddy that originated from the loop current of the Kuroshio southwest of Taiwan, China. One of the gliders crossed the entire eddy and it observed a remarkable warm anomaly of as much as 3.9℃ extending to 500 dbar from the base of the mixed layer. Conversely, a positive salinity anomaly was found to be above 200 dbar only in the anticyclonic eddy, with a maximum value of >0.5 in the mixed layer. Below the mixed layer, water of higher salinity (>34.7) was found, which could have been preserved through constrained vertical mixing within the anticyclonic eddy. The salinity in the upper layer of the anticyclonic eddy was much similar to that of the northwestern Pacific Ocean than the northern South China Sea, reflecting Kuroshio intrusion with anticyclonic eddy shedding from the loop current.     

A Review on the Currents in the South China Sea: Seasonal Circulation, South China Sea Warm Current and Kuroshio Intrusion

Researches on the currents in the South China Sea (SCS) and the interaction between the SCS and its adjacent seas are reviewed. Overall seasonal circulation in the SCS is cyclonic in winter and anticyclonic in summer with a few stable eddies. The seasonal circulation is mostly driven by monsoon winds, and is related to water exchange between the SCS and the East China Sea through the Taiwan Strait, and between the SCS and the Kuroshio through the Luzon Strait. Seasonal characteristics of the South China Sea Warm Current in the northern SCS and the Kuroshio intrusion to the SCS are summarized in terms of the interaction between the SCS and its adjacent seas.     

Eddy Shedding from the Kuroshio Bend at Luzon Strait

TOPEX/POSEDIENT-ERS satellite altimeter data along with the mean state from the Parallel Ocean Climate Model result have been used to investigate the variation of Kuroshio intrusion and eddy shedding at Luzon Strait during 1992–2001. The Kuroshio penetrates into the South China Sea and forms a bend. The Kuroshio bend varies with time, periodically shedding anticyclonic eddies. Criteria of eddy shedding are identified: 1) When the shedding event occurs, there are usually two centers of high Sea Surface Height (SSH) together with negative geostrophic vorticity in the Kuroshio Bend (KB) area. 2) Between the two centers of high SSH there usually exists positive geostrophic vorticity. These criteria have been used to determine the eddy shedding times and locations. The most frequent eddy shedding intervals are 70, 80 and 90 days. In both the winter and summer monsoon period, the most frequent locations are 119.5°E and 120°E, which means that the seasonal variation of eddy shedding location is unclear.     

A numerical study of the summertime flow around the Luzon Strait

Luzon Strait, a wide channel between Taiwan and Luzon islands, connects the northern South China Sea and the Philippine Sea. The Kuroshio, South China Sea gyre, monsoon and local topography influence circulation in the Luzon Strait area. In addition, the fact that the South China Sea is a fairly isolated basin accounts for why its water property differs markedly from the Kuroshio water east of Luzon. This work applies a numerical model to examine the influence of the difference in the vertical stratification between the South China Sea and Kuroshio waters on the loop current of Kuroshio in the Luzon Strait during summer. According to model results, the loop current’s strength in the strait reduces as the strongly stratified South China Sea water is driven northward by the southwest winds. Numerical results also indicate that Kuroshio is separated by a nearly meridional ridge east of Luzon Strait. The two velocity core structures of Kuroshio can also be observed in eastern Taiwan. Moreover, the water flowing from the South China Sea contributes primarily to the near shore core of Kuroshio.