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1.
Intermediate Waters in the East/Japan Sea 总被引:4,自引:0,他引:4
Properties of the intermediate layer in the East/Japan Sea are examined by using CREAMS data taken mainly in summer of 1995.
Vertical profiles of potential temperature, salinity and dissolved oxygen and relationships between these physical and chemical
properties show that the dissolved oxygen concentration of 250 μmol/l, roughly corresponding to 0.6°C at the depth of about
400 db, makes a boundary between intermediate and deep waters. Water colder than 0.6°C has a very stable relationship between
potential temperature and salinity while salinity of the water warmer than 0.6°C is lower in the western Japan Basin than
that in the eastern Japan Basin. The low salinity water with high oxygen corresponds to the East Sea Intermediate Water (ESIW;
<34.06 psu, >250 μmol/l and >1.0°C) which was previously identified by Kim and Chung (1984) and the high salinity water with
high oxygen found in eastern Japan Basin is named as the High Salinity Intermediate Water (HSIW; >34.07 psu, >250 μmol/l and
>0.6°C). Spatial distribution of salinity and acceleration potential on the surface of σϑ = 27.2 kg/m3 shows that the ESIW prevailing in the western Japan Basin is transported eastward by a zonal flow along the polar front near
40°N and a cyclonic gyre in the eastern Japan Basin is closely related to the HSIW.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
2.
Kuh Kim Kyung-Ryul Kim Young-Gyu Kim Yang-Ki Cho Dong-Jin Kang Masaki Takematsu Yuri Volkov 《Progress in Oceanography》2004,61(2-4):157
Water masses in the East Sea are newly defined based upon vertical structure and analysis of CTD data collected in 1993–1999 during Circulation Research of the East Asian Marginal Seas (CREAMS). A distinct salinity minimum layer was found at 1500 m for the first time in the East Sea, which divides the East Sea Central Water (ESCW) above the minimum layer and the East Sea Deep Water (ESDW) below the minimum layer. ESCW is characterized by a tight temperature–salinity relationship in the temperature range of 0.6–0.12 °C, occupying 400–1500 m. It is also high in dissolved oxygen, which has been increasing since 1969, unlike the decrease in the ESDW and East Sea Bottom Water (ESBW). In the eastern Japan Basin a new water with high salinity in the temperature range of 1–5 °C was found in the upper layer and named the High Salinity Intermediate Water (HSIW). The origin of the East Sea Intermediate Water (ESIW), whose characteristics were found near the Korea Strait in the southwestern part of the East Sea in 1981 [Kim, K., & Chung, J. Y. (1984) On the salinity-minimum and dissolved oxygen-maximum layer in the East Sea (Sea of Japan), In T. Ichiye (Ed.), Ocean Hydrodynamics of the Japan and East China Seas (pp. 55–65). Amsterdam: Elsevier Science Publishers], is traced by its low salinity and high dissolved oxygen in the western Japan Basin. CTD data collected in winters of 1995–1999 confirmed that the HSIW and ESIW are formed locally in the Eastern and Western Japan Basin. CREAMS CTD data reveal that overall structure and characteristics of water masses in the East Sea are as complicated as those of the open oceans, where minute variations of salinity in deep waters are carefully magnified to the limit of CTD resolution. Since the 1960s water mass characteristics in the East Sea have changed, as bottom water formation has stopped or slowed down and production of the ESCW has increased recently. 相似文献
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利用2018年夏季在西南黄海的现场调查资料,分析了海温、盐度和溶解氧(dissoloved oxygen,DO)分布特征。海区西侧的江苏沿海有明显的冷水带,冷水带对应表层较高的DO浓度。在海区南侧的长江口附近,盐度由南向北升高,上部海水DO浓度高,下部海水DO浓度低。综合现场观测数据、CCMP (Cross Calibrated Multi-Platform)海面风场遥感数据、AVHRR (NOAA-Advanced Very High Resolution Radiometer)海表温度遥感数据、SMAP (Soil Moisture Active and Passive)海表盐度遥感数据,初步分析了DO的影响因素:夏季偏南风产生从黄海向江苏沿海的上升流,可能有利于形成冷水带和DO高值区;长江冲淡水主要在海水上部向西南黄海扩展,它对水动力的影响及携带的营养盐是形成上层DO高值和底层缺氧现象的重要原因。 相似文献
5.
The first vertical profiles of chlorofluoromethanes (Freons F11 and F12) measured during the austral summer 1987 (INDIGO-3 cruise) in the region of Enderby Land (30°E) and the Princess Elizabeth Trough (90°E) arc presented in relation to hydrological and geochemical characteristics. In the open ocean, transient tracer penetration reaches 1000 m. Off the West Ice Shelf and Enderby Land, a significant decrease in Freons is found below the cold Winter Water and just above the deep oxygen minimum and temperature maximum of the upper Circumpolar Deep Water (200–400 m). In the region off MacRobertson Land, where the oxygen minimum is deeper (1000 m), the Freon gradients are less abrupt. In deep open ocean waters, no Freons were detected in the core of the Circumpolar Deep Water. However, near the continental shelf, we have encountered Freon minima associated with salinity maxima, indicating significant mixing between deep and (recent) ventilated waters. Over the whole water column, a strong zonal contrast emerges in tracer distributions between stations situated to the east and to the west of MacRobertson Land (65°E), which may be associated with the Weddell Gyre extension. Freon maxima associated with oxygen maxima and temperature and salinity minima that characterize Antarctic Bottom Water (AABW) have been found over all the region studied; the tracers indicate three main bottom waters that are related to Weddell Sea, Ross Sea and local origins. At two stations located on the edge of the continental shelf, Freon measurements suggest that the AABW formation was recent, and the tracers' continuity reveals a preferential westward flow of bottom waters. Although it is clear that bottom water formation takes place around 60–70°E, the information is too sparse to specify the source regions. 相似文献
6.
《Deep Sea Research Part I: Oceanographic Research Papers》2000,47(5):789-824
The intermediate water masses in the eastern Atlantic Ocean between 31°N and 53°N were studied by analysis of the distributions of potential temperature, salinity, dissolved nutrients and oxygen. Sub-surface salinity minima are encountered everywhere in the area. At the northern and southern boundary they are connected with the presence of Sub-Arctic Intermediate Water and Antarctic Intermediate Water, respectively, but towards the European ocean margin the sub-surface salinity minima shift to shallower density levels. The sub-surface salinity minima observed west of the Iberian Peninsula represent a water mass formed by winter convection in the Porcupine Sea Bight and the northern Bay of Biscay. These minima gain salt by diapycnal mixing with the underlying Mediterranean Sea Outflow water and with the overlying permanent thermocline. The core of Antarctic Intermediate Water appears to contribute to the formation of Mediterranean Sea Outflow Water since it becomes entrained into the overflow near Gibraltar. This entrainment gives rise to an enhanced concentration of the nutrients in the Mediterranean water in the North Atlantic. The deep salinity minimum, due to the presence of Labrador Sea Water, is restricted mainly to the Porcupine Abyssal Plain. In the Bay of Biscay this water type is strongly modified by enhanced diapycnal mixing near the continental slope. At all intermediate levels the continental slope in the Bay of Biscay seems to be a focal point for water mass modification by diapycnal mixing. Below the core of the Mediterranean Sea Outflow Water the Labrador Sea Water is also strongly modified. Its salinity is strongly enhanced by diapycnal mixing with the overlying core of Mediterranean Sea Outflow Water. An analysis of the oxygen and nutrient data indicates that the large spatial concentration differences at the level of the Labrador Sea Water are caused mainly by ageing of the water. The youngest water is observed at 52°N, and, especially in the Bay of Biscay and off south-west Portugal, the water at levels of about 1700 dbar are strongly enriched in nutrients and depleted in oxygen. 相似文献
7.
Water mass properties along cross-sections of the Kuroshio in the East China Sea (ECS) are investigated in detail. We used temperature, salinity and dissolved oxygen data from 2000 and 2002, together with historical temperature and salinity data from 1987 to 2004. Water properties were divided into two groups: high and low salinities or oxygen at temperatures warmer than 15 and 12 °C, respectively. We found the existence of outer shelf water W2, as defined by clear modes in frequency distributions of salinity and oxygen within various temperature segments. The outer shelf water was different from both Kuroshio Tropical Water (KTW) and coastal water. We mapped horizontal and vertical distributions of W2, along with W1 and KTW. The outer shelf water was distributed with density σ t = 22.5–25.5 over a relatively broad area, from the outer continental shelf to the continental slope, particularly in autumn. Vertical distribution of the water suggests that W2 spread from the outer shelf to just the shelf side of the Kuroshio Current velocity maximum. Seasonal variations are examined with historical data along PN section over 17 years, and suggest that the appearance of W2 is distinct in summer and autumn. By comparing temperature–salinity (T–S) diagrams from Taiwan Strait and east of Taiwan, the outer shelf water (W2) originates from South China Sea Tropical Water (SCSTW), as suggested by Chen, J Geophys Res 110:C05012 (2005). The present study of the ECS clearly shows that SCSTW is transported along the east coast of Taiwan or through the Taiwan Strait into the ECS. It then spreads over a relatively wide area from the outer shelf to just the shelf side of the Kuroshio axis, and there is some horizontal mixing between SCSTW and KTW around the shelf break. 相似文献
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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
10.
东海北部区域底层冷水团的形成及其季节变化 总被引:4,自引:1,他引:4
本文着重探讨东海北部底层冷水(北部冷水)的形成原因、基本特征和季节变化过程。指出北部冷水系冬季黄海沿岸水南下向东海输送低温水并与外海高盐水混合变性形成的。其位置随季节变化而有明显的移动规律,即先由西向东移,而后向北收缩。大体上可分为四个阶段:冷水舌离岸期,北部冷水半封闭期,北缩消亡期和更新期。文中分析了上述变化的原因,较详细地阐述了黄海沿岸水沿陆架下沉与黑潮次—中层混合水爬升的关系及其对北部冷水的影响。分析了北部冷水与黄海冷水团的关系。 相似文献
11.
南极普里兹湾及其邻近海域的水文结构特征和底层水的来源 总被引:8,自引:2,他引:8
利用中国第九次南大洋考察中南极普里兹湾及其邻近海域的CTD资料,分析研究了调查海域的水文结构特征及其该区南极底层水(AABW)的来源.研究结果表明,在研究海域,深水洋区近表层流由西向东流,而在普里兹湾内存在一个气旋型涡.水文结构中最明显的海洋学特征是:(1)绕极深层水(CDW)的涌升现象明显,涌升最强的位置是麦克罗伯逊地以北海域,最明显的深度是50~200m层,暖水涌升将冬季冷水分隔成南北两部分,并在其中形成孤立的暖水块;(2)陆缘水边界明显,这是绕极深层水与南极冷水之间形成的锋面,一般处在次表层水中,大致位于64°~66°S之间;(3)存在着双跃层结构.观测期间,普里兹湾以北探水海域存在着南极底层水,其来源可能有二:一为当地形成,二为源于威德尔海和罗斯海. 相似文献
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苏育嵩 《中国海洋大学学报(自然科学版)》1989,(Z1)
简要介绍了黄海和东海的地理环境概况,着重分析调查海域的环流系统。有如下一些初步看法与结论。 台湾暖流的前缘混合水,可从长江冲淡水底层穿越而影响到苏北沿岸,直到32°N以北的浅水区域。对马暖流西侧的水体是东海混合水,而其东侧为黑潮分支。黄海暖流的流向在不同季节具有规律的摆动。黄海底层冷水团属于季节性水团,其强盛及消衰与温跃层的形成及消亡紧密相关。黄海底层冷水团与中部底层冷水并非每年彼此独立,它们的共同特征甚至比其差异更明显。夏季东海冷水不能借助爬升侵入黄海底层冷水团内部。在济州岛南部区域,中层的逆温、逆盐现象,是由黄海密度环流的扩散效应与东海冷水沿黄海底层冷水团边界的爬升这两个原因而形成的。 相似文献
14.
Hideo Sudo 《Progress in Oceanography》1986,17(3-4)
The water under the main thermocline in the Japan Sea is a single water mass referred to as the Japan Sea Proper Water. It can be defined as having temperature below 2.0°C, salinity above 34.00%, and dissolved oxygen below 7.0 ml 1−1. In the north most of the water above the potential temperature 0.1°C depth (about 800–1000 m) is a mode water, with σθ of 27.32 to 27.34 kg m−3. North of 40°N it has high oxygen (more than 6.00 ml 1−1) with a distinct discontinuity (oxygen-cline) at the bottom of the mode water. The most probable region for the formation of the water is the area north of 41°N between 132° and 134°E. The deeper water probably is formed in the norther area of 43°N, and directly fills the main part of the Japan Basin north of 41°N and east of 134°E. 相似文献
15.
《Deep Sea Research Part II: Topical Studies in Oceanography》2009,56(16):1004-1020
Three sections are used to analyze the physical and chemical characteristics of the water masses in the eastern South Pacific and their distributions. Oceanographic data were taken from the SCORPIO (May–June 1967), PIQUERO (May–June 1969), and KRILL (June 1974) cruises. Vertical sections of temperature, salinity, σθ, dissolved oxygen, nitrate, nitrite, phosphate, and silicate were used to analyze the water column structure. Five water masses were identified in the zone through T–S diagrams: Subantarctic Water, Subtropical Water, Equatorial Subsurface Water, Antarctic Intermediate Water, and Pacific Deep Water. Their proportions in the sea water mixture are calculated using the mixing triangle method. Vertical sections were used to describe the geographical distributions of the water mass cores in the upper 1500 m. Several characteristic oceanographic features in the study area were analyzed: the shallow salinity minimum displacement towards the equator, the equatorial subsurface salinity maximum associated with a dissolved oxygen minimum zone and a high nutrient content displacement towards the south, and the equatorward intermediate Antarctic salinity minimum associated with a dissolved oxygen maximum. The nitrate deficit generated in the denitrification area off Peru and northern Chile is proposed as a conservative chemical tracer for the Equatorial Subsurface Waters off the coast of Chile, south of 25°S. 相似文献
16.
R. Yu. Tarakanov E. G. Morozov A. M. Gritsenko T. A. Demidova N. I. Makarenko 《Oceanology》2013,53(4):432-441
The structure of northerly overflow of Antarctic Bottom Water (AABW) through passages in the East Azores Ridge (37° N) in the East Atlantic from the Madeira Basin to the Iberian Basin is studied on the basis of hydrographic measurements carried out by the Institute of Oceanology, Russian Academy of Sciences (RAS) in October 2011, historical World Ocean Data Base 2009, and recent data on the bottom topography. The overflow of the coldest layers of this water occurs through two passages with close depths at 16° W (Discovery Gap) and at 19°30′ W (nameless Western Gap). It is shown that it is likely that the role of the latter passage in water transport was underestimated in earlier publications because the water (2.01°C) found in the region north of the Western Gap was cooler than in the region north of the Discovery Gap (2.03°C). In 2011, we found a decrease of 0.01°C in the AABW temperature near the bottom compared to previous measurements in 1982 (from 2.011°C to 2.002°C). Analysis of the historical database shows that this decrease is most likely caused by the cooling trend in the abyssal waters in the East Atlantic basins. 相似文献
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东海浮游翼足类(Pteropods)数量分布的研究 总被引:10,自引:1,他引:10
根据1997~2000年东海海域23°30'~33°00'N,118°30'~128°00'E的4个季节海洋调查资料,运用定量、定性方法,探讨了东海浮游翼足类总丰度的平面分布、季节变化及变化的动力学机制.结果表明,东海翼足类总丰度和出现频率有明显的季节变化,均为秋季最高,夏季次之,春季最低;总丰度在各个季节基本上呈东海南部高于北部、外海高于近海的分布趋势;春季的尖笔帽螺(Creseis acicula)、夏季的锥笔帽螺(Creseis virgula)、秋季的蝴蝶螺(Desmopterus papilio)和冬季的马蹄螔螺(Limacina trochiformis)是导致总丰度季节变化的最主要的种类;冬、春和夏3个季节丰度变化及4季总丰度的变化同表层或10m层水温有非常显著的线性相关关系,与底层温度及盐度的相关关系不显著.夏季翼足类高丰度区位于台湾暖流与黑潮暖流的分支处;从夏季到秋季,翼足类随着台湾暖流向北扩展,并在与长江冲淡水,闽浙沿岸水团,黄海水团等交汇处形成高丰度(大于500×10-2个/m3)和较高丰度(250×10-2~500×10-2个/m3)分布区.水温和海流是影响东海翼足类总丰度分布的主要环境因素. 相似文献
19.
采用1987年5-6月中日合作黄东海海域综合调查溶解氧资料,参考有关文献,讨论调查海域溶解氧分布特征及与水团的对应关系。分析结果表明,各水团中溶解氧含量的差异与各水团温盐特性及生物地球化学过程不同有关。通过分析还发现溶解氧对鉴别次表层以深各水团,特别对东海次表层水及黑潮次表层以深各水团,是一个重要的指标。 相似文献
20.
Thermal and haline fronts in the Yellow/East China Seas: Surface and subsurface seasonality comparison 总被引:1,自引:0,他引:1
Seasonal variability of surface and subsurface thermal/haline fronts in the Yellow/East China Seas (YES) has been investigated
using three-dimensional monthly-mean temperature and salinity data from U.S. Navy’s Generalized Digital Environmental Model
(Version 3.0). The density-compensated Cheju-Yangtze Thermal/Haline Front has (northern and southern) double-tongues. The
northern tongue is most evident throughout the depth from December to April. The southern tongue is persistent at the subsurface
with conspicuous haline fronts. The thermal (haline) frontal intensity of the northern tongue is controlled mainly by the
temperature (salinity) variation on the shoreward (seaward) side of the front. The cold water over the Yangtze Bank is influential
in generating the southern tongue and intensifying the Tsushima Thermal Front. The year-round Cheju-Tsushima Thermal Front
is evident throughout the depth and intensifies from July to December. The northern arc of the Yangtze Ring Haline Front is
manifest in spring and is sustained until summer, whereas the southern one is fully developed in summer because of eastward
migration of the Yangtze Diluted Water. The area showing strong frontal intensity in the Chinese Coastal Haline Front shifts
seasonally north and south along the Zhejiang-Fujian coast. The Generation and evolution of YES fronts are closely associated
with YES circulation (inferred from the linkage of the water masses). Moreover, the subsurface temperature/salinity evolution
on the fronts in the Yellow Sea differs from that in the East China Sea owing to local factors such as wintertime vertical
mixing and a summertime strong thermocline above the Yellow Sea Bottom Cold Water. 相似文献