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1.
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
2.
东海陆架表层水温年际变化时空特征分析 总被引:2,自引:2,他引:0
结合东海沿岸嵊山(北)和厦门(南)站1960—2001年海表温度(SST)监测数据与东中国海1982—2011年AVHRR水温资料,讨论了台站监测的空间代表范围,分析了东海陆架SST年际变化的时空特征。结果表明,嵊山和厦门站SST变化分别代表内陆架和台湾海峡。东海陆架52年来SST总体呈升温趋势,冬季最为显著;内陆架的升幅远大于台湾海峡。内陆架水温冬季分别在1977年和1995年发生两次跃升,共升温2.34℃;春、夏、秋季均在1994年发生冷暖转折,分别升高1.19℃、1.43℃和1.16℃。台湾海峡水温冬季在1989年跃升0.91℃,夏季在1987年跃升0.38℃,春、秋季则在1996—1997年间分别升温0.80℃和0.58℃。全年水温变化最大处在长江口附近内陆架海区,可能的主导因素是低盐水与外海水混合:随季风、降水、径流变化的沿岸流、长江冲淡水和台湾暖流给该区域带来不同水团,使得热量向下层输运减少,从而导致东海内陆架升温快于其它海区。 相似文献
3.
本文在对位于黄海南部陆架上的朝连岛站30年水温资料进行分析时发现,该站的表层水温有周期大于20个月的低频振动,其中以准两年周期和6年周期最显著。陆架水温的这种低频振动是对东亚季风异常的响应。这种低频振动在冬季与渤海冰情的变化同步;在夏季与黄海底层冷水团的强弱相关。同时,这种低频振动在对马暖流上也有一定的反映。 相似文献
4.
The optimum multiparameter (OMP) method was often used to determine the percentages of water masses based on temperature, salinity and other parameters, like nutrient or dissolved oxygen (DO). There are a number of water masses in the East China Sea (ECS), a marginal sea of the western Pacific Ocean. However, it is difficult to clarify the proportion of water masses using traditional parameters, such as temperature, salinity, nutrient or DO because of the occurring of intensive biogeochemical processes in the near shore and shelf areas. Here, we reported the use of 234U/238U activity ratio embedded in the OMP method. The results indicate that seawater in the northern ECS mainly consisted of the estuarine water of Changjiang River (CEW), Kuroshio water (KW), and Yellow Sea Coastal Current (YSCC). In March 2017, the CEW only influenced the offshore waters shallower than 30 m; the KW affected the east edge and the YSCC contributed more than 75% in the northern ECS. 相似文献
5.
OntheoriginoftheTsushimaWarmCurrentWater¥TangYuxiangandHeung-JaeLie(FirstinstituteOfOceanography,StateOceanicAdministration,Q... 相似文献
6.
The connectivity between the interannual salinity variations in the Tsushima and Cheju Straits has been investigated on the
basis of historical hydrographic data. Salinity in the Cheju Strait correlates positively with that in the western channel
of the Tsushima Strait, but does not show a significant correlation with that in the eastern channel. Empirical orthogonal
function (EOF) and singular value decomposition (SVD) analyses of temperature and salinity in the Cheju Strait revealed that
salinity in the strait is associated with the cold bottom water in summer. Drastic freshening in the Cheju Strait occurs in
a period when the Cheju Current intensifies. The results allow us to hypothesize that the mechanism of interannual salinity
variations in the Cheju Strait and western channel of the Tsushima Strait is as follows. The intrusion of cold bottom water
into the Cheju Strait in summer intensifies the Cheju Current by increasing the baroclinicity. Since colder bottom water develops
a stronger eastward surface current, the larger volume of the Changjiang diluted water is drawn into the strait, which results
in a lower salinity condition in the Cheju Strait. As the water in the Cheju Strait flows into the western channel of the
Tsushima Strait, salinity in the western channel varies synchronously. This hypothesis is supported by SVD analysis of temperature
in the Cheju Strait and salinity in the Tsushima Strait. The salinity condition in the East China Sea is suggested to be another
important influence on salinity in the western channel of the Tsushima Strait. 相似文献
7.
基于ROMS(Regional Ocean Modeling System)模式,对西北太平洋海域进行了水平分辨率高达4km的水动力环境数值模拟,该分辨率可以很好地分辨我国东海陆架环流以及中尺度涡旋等过程,此外模式考虑了8个分潮,模式结果很好地再现了黄、东海陆架环流等。基于模式结果,对"桑吉"号泄漏物质可能的扩散和迁移轨迹进行了数值模拟分析。在"桑吉"号沉船位置的表、底Ekman层内,释放拉格朗日粒子和示踪物来示踪"桑吉"号泄漏物质的可能影响范围。拉格朗日粒子和示踪物模拟结果表明:在未来3个月,"桑吉"号泄漏物质对我国黄海的影响较小,其主要随着对马暖流进入日本海和随着黑潮进入日本九州以南的太平洋海域。随着冬、春的季节转换,三个月后,北风会减弱,减弱风场的试验表明,风场减弱会减少泄漏物质向黄海的输送。5月份后黄海冷水团逐渐形成,由于斜压效应,在黄海深层水中会逐渐建立起气旋式环流,从而进一步阻碍了"桑吉"号泄漏物质向黄海的输送,该气旋式环流有利于"桑吉"号泄漏物质通过对马海峡向日本海的输送,而会抑制底层泄漏物质向我国黄海西侧的输送。 相似文献
8.
Many typhoons pass through the East China Sea(ECS) and the oceanic responses to typhoons on the ECS shelf are very energetic. However, these responses are not well studied because of the complicated background oceanic environment. The sea surface temperature(SST) response to a severe Typhoon Rananim in August 2004 on the ECS shelf was observed by the merged cloud-penetrating microwave and infrared SST data. The observed SST response shows an extensive SST cooling with a maximum cooling of 3°C on the ECS shelf and the SST cooling lags the typhoon by about one day. A numerical model is designed to simulate the oceanic responses to Rananim.The numerical model reasonably simulates the observed SST response and thereby provides a more comprehensive investigation on the oceanic temperature and current responses. The simulation shows that Rananim deepens the ocean mix layer by more than 10 m on the ECS shelf and causes a cooling in the whole mixed layer. Both upwelling and entrainment are responsible for the cooling. Rananim significantly deforms the background Taiwan Warm Current on the ECS shelf and generates strong Ekman current at the surface. After the typhoon disappears, the surface current rotates clockwise and vertically, the current is featured by near inertial oscillation with upward propagating phase. 相似文献
9.
Kosuke Mori Takeshi Matsuno Tomoharu Senjyu Naoki Hirose In-Seong Han 《Journal of Oceanography》2009,65(3):301-310
Temporal variations in temperature and salinity observed in 2004 were investigated on a short time scale in the Tsushima Strait.
The data were obtained by long-term in situ measurements at Mitsushima and Futaoi Island using an instrument equipped with
a piston-type wiper to avoid biofouling. In addition, the temperature and salinity values of the surface layer obtained by
a commercial ferryboat between Hakata and Busan were used to investigate their spatiotemporal variations. Temperature and
salinity variations with a time scale of several days had a negative correlation in the summer. This evidence suggests that
a warm and less saline water mass, which is considered to be mainly the Changjiang Diluted Water (CDW), flowed intermittently
through the Tsushima Strait in summer. In late July 2004, a large low-salinity water mass was detected in the Tsushima Strait.
At that time, the freshwater transport through the Tsushima Strait transiently reached about 12 × 104 m3s−1, which is estimated from observed acoustic Doppler current profiler (ADCP) data along a ferryboat line and inferred salinity
profiles. This estimated value is more than double the maximum of the climatological monthly mean of the Changjiang discharge.
Furthermore, salinity and surface current data obtained by high frequency ocean radar (HF radar) indicate that water properties
at Mitsushima may occasionally represent part of the water flowing through the western channel via a countercurrent, although
Mitsushima is geographically located in the eastern channel. 相似文献
10.
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
11.
~(234)U/~(238) as a potential tracer for tracking water masses mixing in the northern East China Sea
《海洋学报(英文版)》2021,(4)
The optimum multiparameter(OMP) method was often used to determine the percentages of water masses based on temperature, salinity and other parameters, like nutrient or dissolved oxygen(DO). There are a number of water masses in the East China Sea(ECS), a marginal sea of the western Pacific Ocean. However, it is difficult to clarify the proportion of water masses using traditional parameters, such as temperature, salinity, nutrient or DO because of the occurring of intensive biogeochemical processes in the near shore and shelf areas. Here, we reported the use of ~(234)U/~(238)Uactivity ratio embedded in the OMP method. The results indicate that seawater in the northern ECS mainly consisted of the estuarine water of Changjiang River(CEW), Kuroshio water(KW), and Yellow Sea Coastal Current(YSCC). In March 2017, the CEW only influenced the offshore waters shallower than30 m; the KW affected the east edge and the YSCC contributed more than 75% in the northern ECS. 相似文献
12.
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
13.
The distributional features of sea surface temperature and salinity(SST and SSS) in the Taiwan Straits have been analyzed using the SST and SSS underway measurements in August,1999.The characteristics of SST and SSS are summarized as foloows:There are several upwellings and diluted water in the Taiwan Straits.The upwellings are divided into two kinds:those along the western coast of the Taiwan Straits and those around the Taiwan Shoal.There are three sources of diluted water:diluted water of the Jiulongjiang River,diluted water of the Zhujiang River and diluted water of the Minjiang River. 相似文献
14.
东海温度锋的分布特征及其季节变异 总被引:8,自引:4,他引:8
根据1934-1988年东海水文观测资料,重点分析东海温度锋的分布特征及其季节变异,并结合近期中日黑潮合作调查研究成果,初步探讨温度锋季节变异和水团演变的关系,所得主要结论是:(1)东海不仅常年存在浙闽沿岸锋,东海北部陆架锋和黑潮锋,而且、春、夏两季,在东海南部还出现一条东海中部出架锋。(2)江海温度锋季节变化的特点是:冬季,锋的宽度和强度皆是表层最强,夏季,表层温度锋仅出现在浙江近岸小范围海域。 相似文献
15.
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
16.
In 1999, synoptic and hydrological conditions in the western Bering Sea were characterized by negative SST and air temperature anomalies, extensive ice coverage and late melting. Biological processes were also delayed. In 1999, the average zooplankton biomass was 1.76 g/m3, approximately half the average 3.07 g/m3 in 1998. Pacific salmon migrated to the northeastern Kamchatka streams two weeks later. This contrasts with 1997 (spring and summer) and 1998 (summer) when positive SST anomalies were widely distributed throughout the northwestern Bering Sea shelf. Since the second half of the 1990s, seasonal atmospheric processes developed over the western Bering Sea that were similar to those of the cold decades of the 1960–1970s. A meridional atmospheric circulation pattern began to replace zonal transport. Colder Arctic air masses have shifted over the Bering Sea region and shelf water temperatures have cooled considerably with the weakening of zonal atmospheric circulation. Temperature decreased in the cold intermediate layer during its renewal in winter. Besides, oceanic water inflow intensified into the Bering Sea in intermediate layers. Water temperature warmed to 4°C and a double temperature maximum existed in the warm intermediate layer in late summer in both 1997 and 1998. Opposing trends of cold water temperature and a warm intermediate layer led to an increase of vertical gradients in the main thermocline and progressing frontogenesis. It accelerates frontal transport and can be regarded as a chief cause of increased water exchange with the Pacific Ocean. 相似文献
17.
Hydrographic conditions in the Tsushima Strait revisited 总被引:1,自引:1,他引:0
Long-term averaged temperature and salinity distributions in the Tsushima Strait are investigated on the basis of a concurrent
dataset of the eastern and western channels during 1971–2000. Both temperature and salinity show a clear seasonal variation
with weak and strong stratifications in December–April and June–October, respectively. The largest standard deviations occur
in summer around the thermocline for temperature and in the surface layer for salinity. This indicates large interannual variability
in the development of a thermocline and low salinity water advection from the East China Sea. The water masses in both channels
are distinctly different from each other; the water in the western channel is generally colder and fresher than that in the
eastern channel throughout the year. Baroclinic transport based on the density distributions shows a seasonal variation with
a single peak in August for the eastern channel and double peaks in April and August for the western channel. However, this
cannot explain the seasonal variation in the total volume transport estimated from the sea level differences across the channels.
The spatial distribution of baroclinic transport shows a year-round negative transport towards the East China Sea behind the
Iki Island in the eastern part of the eastern channel. This negative transport reflects the baroclinic structure between the
offshore Tsushima Current Water and cold coastal water. The corresponding southwestward currents are found in both Acoustic
Doppler Current Profiler (ADCP) and high frequency (HF) radars observations. 相似文献
18.
Tomoharu Senjyu 《Journal of Oceanography》1999,55(2):111-122
In the southern Japan Sea there is a salinity minimum layer between the Tsushima Current Water and the Japan Sea Proper Water.
Since the salinity minimum corresponds to the North Pacific Intermediate Water, it is named the Japan Sea Intermediate Water
(JIW). To examine the source and circulation of JIW, the basin-wide salinity minimum distribution was investigated on the
basis of hydrographic data obtained in 1969. The young JIW, showing the highest oxygen concentration and the lowest salinity,
is seen in the southwestern Japan Sea west of 133°E, while another JIW with lower oxygen and higher salinity occupies the
southeastern Japan Sea south of the subpolar front. Since the young JIW shows high oxygen concentrations, high temperatures
and low densities, the source of the water is probably in the surface layer. It is inferred that the most probable region
of subduction is the subarctic front west of 132°E with the highest oxygen and the lowest salinity at shallow salinity minimum.
In addition, property distributions suggest that JIW takes two flow paths: a eastward flow along the subarctic front and an
southward flow toward the Ulleung Basin. On the other hand, a different salinity minimum from JIW occupies the northern Japan
Sea north of the subarctic front, which shows an apparently higher salinity and high oxygen concentration than JIW. However,
this salinity minimum is considered not to be a water mass but to be a boundary between overlying and underlying water masses.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
19.
The sea surface temperature distribution across the Tsushima Strait was monitored over a one-year period on board the ferry Kampu which runs between Shimonoseki, Japan and Pusan, Korea. A cold water region is always observed just near the Korean Coast, and a sharp temperature front is always present in the western channel. A temperature maximum or a warm core is usually found just on the southeast side of the front. The position of the warm core exhibits large short period fluctuations, but no significant seasonal variation is found. Sudden temperature increases followed by sudden temperature decreases are frequently observed in the temporal variation curves at fixed positions during the warming season from April to August. Such events are related to temperature maxima found sporadically in the temperature distribution in the eastern channel during this season, and seem to be caused by warm water intrusion into the Tsushima Strait from the East China Sea. 相似文献
20.
由黑潮派生的各种暖流对东海而言是重要的热能来源,它们的态势会极大地影响东海的温度分布,从而影响到生态系统的变化和发展.通过对2003年度东海暖流主干温度、暖舌前锋位置进行空间分析,并与历史状况比较,结果表明在2003年春夏黑潮和对马暖流的温度和势力与常年差不多,台湾暖流及黄海暖流比常年要弱一些;夏初各暖流都出现了较大幅度低于常年的状况,先是黑潮,然后台湾暖流、对马暖流最后是黄海暖流.而秋冬两季除黄海暖流只比常年略强一些外,各暖流均呈强势,不但温度较高,而且暖舌的伸展距离比常年有不同程度增加.特别是黑潮、台湾暖流和对马暖流在冬季都接近历史最强水平,而相对较弱的黄海暖流也比多年平均略强一些. 相似文献