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1.
The Current System in the Yellow and East China Seas 总被引:18,自引:1,他引:18
During the 1990s, our knowledge and understanding of the current system in the Yellow and East China Seas have grown significantly
due primarily to new technologies for measuring surface currents and making high-resolution three-dimensional numerical model
calculations. One of the most important new findings in this decade is direct evidence of the northward current west of Kyushu
provided by satellite-tracked surface drifters. In the East China Sea shelf region, these recent studies indicate that in
winter the Tsushima Warm Current has a single source, the Kuroshio Branch Current in the west of Kyushu, which transports
a mixture of Kuroshio Water and Changjiang River Diluted Water northward. In summer the surface Tsushima Warm Current has
multiple sources, i.e., the Taiwan Warm Current, the Kuroshio Branch Current to the north of Taiwan, and the Kuroshio Branch
Current west of Kyushu. The summer surface circulation pattern in the East China Sea shelf region changes year-to-year corresponding
to interannual variations in Changjiang River discharge. Questions concerning the Yellow Sea Warm Current, the Chinese Coastal
Current in the Yellow Sea, the current field southwest of Kyushu, and the deep circulation in the Okinawa Trough remain to
be addressed in the next decade.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
2.
Heung-Jae Lie Cheol-Ho Cho Jae-Hak Lee Suk Lee Yuxiang Tang 《Journal of Oceanography》2000,56(2):197-211
The Cheju Warm Current has been defined as a mean current that rounds Cheju-do clockwise, transporting warm and saline water to the western coastal area of Cheju-do and into the Cheju Strait in the northern East China Sea (Lie et al., 1998). Seasonal variation of the Cheju Warm Current and its relevant hydrographic structures were examined by analyzing CTD data and trajectories of satellite-tracked drifters. Analysis of a combined data set of CTD and drifters confirms the year-round existence of the Cheju Warm Current west of Cheju-do and in the Cheju Strait, with current speeds of 5 to 40 cm/s. Saline waters transported by the Cheju Warm Current are classified Cheju Warm Current water for water of salinity greater than 34.0 psu and modified Cheju Warm Current for water having salinity of 33.5–34.0 psu. In winter, Cheju Warm Current water appears in a relatively large area west of Cheju-do, bounded by a strong thermohaline front formed in a "" shape. In summer and autumn, the Cheju Warm Current water appears only in the lower layer, retreating to the western coastal area of Cheju-do in summer and to the eastern coastal area sometimes in autumn. The Cheju Warm Current is found to flow in the western channel of the Korea/Tsushima Strait after passing through the Cheju Strait, contributing significantly to the Tsushima Warm Current. 相似文献
3.
夏季台湾海峡水及黑潮次表层涌升水向东海近陆架区营养盐输送通量的估算 总被引:2,自引:1,他引:1
According to historical mean ocean current data through the field observations of the Taiwan Ocean Research Institute during 1991–2005 and survey data of nutrients on the continental shelf of the East China Sea(ECS) in the summer of 2006, nutrient fluxes from the Taiwan Strait and Kuroshio subsurface waters are estimated using a grid interpolation method, which both are the sources of the Taiwan Warm Current. The nutrient fluxes of the two water masses are also compared. The results show that phosphate(PO4-P), silicate(SiO3-Si) and nitrate(NO3-N) fluxes to the ECS continental shelf from the Kuroshio upwelling water are slightly higher than those from the Taiwan Strait water in the summer of 2006. In contrast, owing to its lower velocity, the nutrient flux density(i.e., nutrient fluxes divided by the area of the specific section) of the Kuroshio subsurface water is lower than that of the Taiwan Strait water. In addition, the Taiwan Warm Current deep water, which is mainly constituted by the Kuroshio subsurface water, might directly reach the areas of high-frequency harmful alga blooms in the ECS. 相似文献
4.
Three warm currents, the Kuroshio, its shelf intrusion branch in the northeast of Taiwan and the Taiwan Warm Current (hereafter TWC), dominate the circulation pattern in the East China Sea (hereafter ECS). Their origination, routes and variation in winter and summer are studied. Their relationship with four major high and low temperature centers is analyzed. Differing from the previous opinion, we suggest that the four major centers are generated to a great extent by the interaction of the currents in the ECS. In summer, a cold water belt in the northeast of Taiwan is preserved from winter between the Kuroshio and the TWC. The shelf intrusion branch of the Kuroshio separates the water belt, and two low temperature centers generate in the northeast of Taiwan. In the southern ECS, the TWC transports more heat flux northward to form a warm pool. But it is separated in the lower layer by the cold water driven by the intrusion branch of the Kuroshio. So the TWC and the intrusion branch of the Kuroshio play a dominating role to generate the high temperature center. The interaction among the eastward TWC, the northward Tsushima Warm Current (hereafter TSWC) and the southward Su Bei Coastal Flow (hereafter SBCF) generates the low temperature center in the northern ECS. In winter, the strengthening of the shelf intrusion branch of the Kuroshio obscures the two low temperature centers in the northeast of Taiwan. For the weakening of the TWC, the high temperature center in the southern ECS vanishes, and the low temperature center in the northern ECS shifts to south. 相似文献
5.
东海西部陆架海域水团的季节特征分析 总被引:3,自引:1,他引:2
On the basis of the CTD data and the modeling results in the winter and summer of 2009, the seasonal characteristics of the water masses in the western East China Sea shelf area were analyzed using a cluster analysis method. The results show that the distributions and temperature-salinity characteristics of the water masses in the study area are of distinct seasonal difference. In the western East China Sea shelf area, there are three water masses during winter, i.e., continental coastal water(CCW), Taiwan Warm Current surface water(TWCSW) and Yellow Sea mixing water(YSMW), but four ones during summer, i.e., the CCW, the TWCSW, Taiwan Warm Current deep water(TWCDW) and the YSMW. Of all, the CCW, the TWCSW and the TWCDW are all dominant water masses. The CCW, primarily characterized by a low salinity, has lower temperature, higher salinity and smaller spatial extent in winter than in summer. The TWCSW is warmer, fresher and smaller in summer than in winter, and it originates mostly from the Kuroshio surface water(KSW) northeast of Taiwan, China and less from the Taiwan Strait water during winter, but it consists of the strait water and the KSW during summer. The TWCDW is characterized by a low temperature and a high salinity, and originates completely in the Kuroshio subsurface water northeast of Taiwan. 相似文献
6.
Atsuhiko Isobe 《Journal of Oceanography》1999,55(2):185-195
Using a temperature data set from 1961 to 1990, we estimated the monthly distribution of the vertically integrated heat content
in the East China Sea. We then drew the monthly map of the horizontal heat transport, which is obtained as the difference
between the vertically integrated heat content and the surface heat flux. We anticipate that its distribution pattern is determined
mainly due to the advection by the ocean current if it exists stably in the East China Sea. The monthly map of the horizontal
heat transport showed the existence of the Taiwan-Tsushima Warm Current System (TTWCS) at least from April to August. The
T-S (temperature-salinity) analysis along the path of TTWCS indicated that the TTWCS changes its T-S property as it flows
in the East China Sea forming the Tsushima Warm Current water. The end members of the Tsushima Warm Current water detected
in this study are water masses in the Taiwan Strait and the Kuroshio surface layer, the fresh water from the mainland of China,
and the southern tip of the Yellow Sea Cold Water extending in the northern part of the East China Sea.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
7.
By using Acoustic Doppler Current Profiler (ADCP) measurements with the four round-trips method to remove diurnal/semidiurnal
tidal currents, the detailed current structure and volume transport of the Tsushima Warm Current (TWC) along the northwestern
Japanese coast in the northeastern Japan Sea were examined in the period September–October 2000. The volume transport of the
First Branch of the TWC (FBTWC) east of the Noto Peninsula was estimated as approximately 1.0 Sv (106 m3/s), and the FBTWC continued to flow along the Honshu Island to the south of the Oga Peninsula. To the north of the Oga Peninsula,
the Second Branch of Tsushima Warm Current and the eastward current established by the subarctic front were recombined with
the FBTWC and the total volume transport increased to 1.9 Sv. The water properties at each ADCP line strongly suggested that
most of the upper portion of the TWC with high temperature and low salinity flowed out to the North Pacific as the Tsugaru
Warm Current. In the north of the Tsugaru Strait, the volume transport of the northward current was observed to be as almost
1 Sv. However, the component of the TWC water was small (approximately 0.3 Sv). 相似文献
8.
A Review on the Currents in the South China Sea: Seasonal Circulation, South China Sea Warm Current and Kuroshio Intrusion 总被引:47,自引:4,他引:43
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. 相似文献
9.
Variability of the Kuroshio in the East China Sea in 1993 and 1994 总被引:11,自引:1,他引:10
INTRODUCTIONTherearemanyworksabouttheKuroshioVTintheEastChinaSeaanditsseasonalvariabil*ThisprojectwassupportedbytheNationalNaturalScienceFoundationofChinaundercontractNo.49776287.1.SecondinstituteofOceanography,StateOceanicAdministration,Hangzhou310012,Chinaity(Guan,1988;Nishizawaetal.,1982;SunandKaneko,1993;Yuanetal.,1990,1993,1994,1995).Thecomputationmethodusedtobethedynamicmethod(Guan,1988;Nishizawaetal.,1982;SunandKaneko,1993),butrecentlytheinverseandthemodifiedinversemetho… 相似文献
10.
通过对南海东北部及台湾海峡邻近海域环流产生影响的各个动力因子进行量级分析,在Hurlburt等人数值模式的基础上,建立起分区性的正压、斜压耦合模式,以便能反映大陆架、大陆坡变化剧烈的底形效应对边缘海环流的影响。将该模式用于南海东北部及台湾海峡附近环流的数值研究。初步的试验计算结果表明,耦合模式能克服两层模式易发生"交面"和"交底"等现象的缺点,同时能反映斜压效应及底形效应的影响,使模拟的计算结果更切合实际,即:(1)黑潮通过巴士海峡侵入南海海域,并导致东沙群岛附近终年存在一个气旋涡;(2)台湾海峡西南海域的大陆架-大陆坡底形效应十分重要;(3)海水在台湾海峡的流动基本上为N向流动,流量约为2×10~6m~3·s-1;(4)模式中有类似于南海暖流的海流出现。 相似文献
11.
东中国海环流及其季节变化的数值模拟 总被引:1,自引:0,他引:1
关于东中国海环流的研究,国内外学者已做了大量的工作。早期科学家们主要依赖于对温盐资料和少数测流资料的分析研究对渤、黄、东海的环流结构有了较系统和深入的认识。东中国海环流是由一个气旋式的“流涡”组成,东侧主要是北上的黑潮-对马暖流-黄海暖流及其延伸部分;西侧为南下的沿岸流系。黑潮对东中国海环流的影响是如此之大,以致于除了某些局部区域外,上述海域主要流系的冬、夏季分布形式比较相似而无本质上的差异(胡敦欣等,1993)。但本文所研究海域正处于世界上最显著的季风区,冬、夏季盛行风向基本相反,过渡季节(春、秋季)风向多变,风力减弱;海洋热盐结构季节变化明显(如冬季混合强,而夏季层化明显等),这些因素都使得东中国海环流存在着较明显的季节变化。
自20世纪80年代以来,东中国海环流的数值模拟工作逐步展开,并已成为研究环流结构及其形成机制的强有力工具。但由于数值模式本身以及计算方案的缺陷(如有些学者用固定的风场、温盐场对东中国海环流进行诊断模拟等)和观测资料的不足,数值模拟的结果难以得到验证,渤、黄、东海的环流研究中仍有大量的问题存在争议,以待澄清。例如,台湾暖流的来源、流径;对马暖流的来源;夏季黄海暖流的流径以及黄海冷水团环流等均有不同的论述。对黄、东海环流季节变化的数值模拟工作也较少,多用冬、夏典型月份的风场强迫积分至稳定态,给出冬、夏季环流,这种做法值得商榷。三维环流模式很难在1个月内达到稳定态,尤其是夏季层化明显、风力减弱的情况下,非常定风场的影响更应引起人们的重视。
本文采用比较符合实际的计算方案,用年循环风场和海面热通量场为外强迫,对渤、黄、东海的环流及其季节变化进行了模拟,并对一些争议问题进行了探讨。 相似文献
12.
本文通过二维数值模拟对1986年6月~1988年12月东海对马暖流水的来源问题进行了初步探讨,结果得出东海对马暖流水的来源基本上分为三种类型:(1)东海对马暖流水主要为东海黑潮水继续北上部分构成;(2)东海对马暖流水由东海黑潮水、东海陆架水以及东海北部黄海大陆沿岸水几部分混合而成;(3)东海对马暖流水几乎全部由东海北部的黄海大陆沿岸水构成。模拟与实测结果基本一致. 相似文献
13.
利用1个正压的数值模式研究风应力、黑潮对南海东北部及台湾海峡环流的影响,结果为:(1)以风应力为驱动机制时其流态特别是在台湾海峡的流动具有季节性,但未反映南海黑潮分支的存在;在冬季也未见有南海暖流出现,但在东沙群岛附近海域终年存在着1个气旋涡;(2)以黑潮为驱动机制时,黑潮通过巴士海峡侵入南海海域,并导致东沙群岛附近气旋性涡旋的形成。另外,模式体现黑潮南海分支、南海暖流及台湾暖流的存在,并表明广东沿岸大陆架坡折区底形效应的重要性;(3)以风应力及黑潮入流作为联合驱动机制时,模式的结果似为第1,2种情形结果的叠加。 相似文献
14.
依据自适应数值模型,模拟了东中国海冬、夏季三维斜压Lagrange环流。模拟发现:台湾暖流的上层水来自台湾海峡入流和台湾东北黑潮的表层水;50m以下的深底层水主要由台湾东北黑潮的次表层水入侵陆架生成。冬季对马暖流外海一侧主要由黑潮水构成,而其近陆一侧由台湾暖流和陆架混合水构成,西朝鲜沿岸流在济州海峡汇入对马暖流;夏季它还包含转向后的长江冲淡水。冬季黄海暖流并非对马暖流的直接分支,黄海暖流水是对马暖流水和陆架水混合而成,这与传统观点相悖,而与中韩黄海水循环动力学合作调查结果一致。黄海暖流东西两侧分别为2支向南流动的滑岸流。夏季黄海环流构成基本封闭的逆时针环流。冬季渤海环流主要有一逆时针大环流,但辽东湾的环流是顺时针向的。渤海环流冬强夏弱,水流在渤海海峡北进南出。 相似文献
15.
Characteristics of water mass under the surface mixed layer in Tsushima Straits and the southwestern Japan Sea in autumn 总被引:1,自引:0,他引:1
Tetsutaro Takikawa Akihiko Morimoto Goh Onitsuka Atsushi Watanabe Masatoshi Moku 《Journal of Oceanography》2008,64(4):585-594
Two different cold waters were found under the surface mixed layer in Tsushima Straits and the southwestern Japan Sea in autumn
2004. One is cold saline water with a low concentration of dissolved oxygen, and the other is cold less saline water with
a high concentration of dissolved oxygen. The older saline water originates from the bottom of the East China Sea, strongly
influenced by the Kuroshio water with high salinity. The bottom density in the eastern channel of the Tsushima Straits is
coincident with that of the East China Sea in autumn, corresponding to the season when the cold saline water was frequently
found in the Tsushima Straits. The newer less saline water originates from the front of Tsushima Warm Current between the
Tsushima Warm Current water and the surface cold water in the Japan Sea. This water is formed by subduction above the isopycnal
surface from the front of the Tsushima Warm Current. 相似文献
16.
Winter counter-wind currents off the southeastern China coast: A review 总被引:11,自引:1,他引:11
This review covers the discovery and studies of the year-round northeastward currents off the southeastern China coast, paying
special attention to its upwind characteristic in winter, mainly focusing on work by Chinese oceanographers. This current
system is a prominent and unique phenomenon in the shelf circulation of the world ocean. The general features of the current
system are summarized. The evidence for the existence and the variation of the three parts of the currents—the South China
Sea Warm Current, the Taiwan Strait Warm Current and the Taiwan Warm Current—are separately elucidated. The formation mechanisms
of the current as a whole are explained using dynamic analysis and numerical simulation results. Some suggestions for further
studies are also made. 相似文献
17.
依据黄、东海环流的的动力学模型 ,运用“流速分解法”对黄、东海正压环流进行了数值模拟。计算结果表明冬季黄海正压环流主要受风应力影响 ,基本形态为黄海暖流由济州岛西南进入南黄海中部 ,其东西两侧分别为两支向南流动的沿岸流 ;夏季主要受到潮致体力的影响 ,为一逆时针涡旋。东海环流主要是边界力作用驱动的结果 ,东海黑潮、台湾暖流和对马暖流较稳定。冬季风应力对东海环流表层流场有消弱作用 ,在夏季则有一定增强作用。 相似文献
18.
本文全面地分析了此段海流的流路与流速结构,首次提出研究海域近底层的环流示意图。指出在夏季,韩国南岸和日本九州北岸均存在着一支南下的逆流,九州西岸出现两种或多种形式的流路。对马暖流在源地流速很弱,流向不稳定,流路时隐时显不明显,只有离开源地后才逐渐显示出一支海流轮廓;强流区在朝鲜海峡附近。该海流可明显地划分为三段。流速夏强冬弱,夏季流幅宽约80km。 相似文献
19.
东海和南黄海夏季环流的斜压模式 总被引:17,自引:6,他引:17
基于拉格朗日余流及其输运过程的一种三维空间弱非线性理论,引进了黑潮边界力及长江径流,给出了东海和南黄海的夏季环流及上升流区的分布。计算结果表明:在黑潮西侧存在着台湾-对马暖流系统;进入朝鲜海峡的对马暖流来自台湾暖流、黑潮、东海混合水和西朝鲜沿岸流;黄海暖流主要来源于东海混合水,表面有部分来自对马暖流;闽浙沿岸存在上升流区且构成一带状区域;在长江口外、东海东北部和陆坡上也存在在上升流式;陆坡处上升流 相似文献
20.
Heung-Jae Lie 《海洋学报(英文版)》1999,18(3):355-373
INTRODUCTIONTheHuanghaiSea(hereafterHS)isashallow,semi-enclosedbasinsurroundedbytheChina'sMainlandtoitswestandmorth,andbytheKoreaPeninsulatOtheeast.TheHSreceivesabundantdischargeoffreshwaterandland-basedmaterialsthroughriversfromChinaandKorea,which ThisstudywassupportedbyagrantfromtheKoreaMinistryofaudienceandTechnoing.maybeaccumulatedpartlyinsidethebasinforacertainpenedormoveoutofthebasinintothenorthwesternEastChinaSea.TheHScirculationisknowntobemostlydependentuPOnsurfacewindfie… 相似文献