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1.
西南黄海近岸低盐水体的来源与输送机制 总被引:1,自引:0,他引:1
In the southwestern Yellow Sea there is a low-salinity and turbid coastal water,the Subei Coastal Water(SCW).The origins of freshwater contents and thus the dissolved terrigenous nutrients in the SCW have been debated for decades.In this study,we used a well-validated numerical model to quantify the contributions of multiple rivers,i.e.,the Changjiang River in the south and the multiple Subei local rivers(SLRs) in the north,in forming this yearround low-salinity coastal water.It is found that the freshwater contents in the SCW is dominated by the Changjiang River south of 33.5°N,by the SLRs north of 34.5°N,and by both sources in 33.5°–34.5°N.Overall,the Changjiang River contributes ~70% in the dry season and ~80% in the wet season of the total freshwater contents in the SCW,respectively.Dynamics driving the Changjiang River Plume to flow northward is the tidal residual current,which can even overwhelm the wind effects in winter seasons.The residual currents turn offshore near the Old Yellow River Delta(OYRD) by the collision of the two tidal wave systems,which transport the freshwater from both sources into the interior Yellow Sea.Water age experiments show that it takes 50–150 d for the Changjiang River Plume to reach the SCW in the spring and summer seasons,thus there is a 2-month lag between the maximum freshwater content in SCW and the peak Changjiang River discharge.In the winter and autumn seasons,the low salinity in inner SCW is the remnant Changjiang River diluted water arrived in the previous seasons. 相似文献
2.
利用普林斯顿海洋环流模式(POM),通过一系列的理想试验,探讨了夏季长江冲淡水的扩展机制。结果表明:(1)倾斜底形是夏季长江冲淡水向东北偏转的一个必要条件;夏季冲淡水向东北偏转是南风、斜压效应和底形的共同作用的结果,其中风应力和底形的相互作用占主导地位;单纯的底形东倾不能使冲淡水向北偏转。平底时,南风和淡水浮力强迫都不能使冲淡水向北偏转。(2)无风时,人海淡水可以在河口附近强迫出一个反气旋涡旋和贴岸南下的狭窄的沿岸流,反气旋涡旋与淡水浮力强迫(斜压效应)有关,南下沿岸流则与质量输入有关;平底时,反气旋涡旋位于河口正东,倾斜底形时,反气旋涡旋向北拉伸,冲淡水的一部分沿岸向北扩展;人海淡水在河口附近强迫出一个闭合的垂直环流圈:上层为离岸流,淡水向外海扩展,约在离岸30—45km处有下降流;低层有高盐水沿海底流向河口,约在离河口。lOkm处与向海的径流相遇,引起上升流。 相似文献
3.
Yang Ding Xianwen Bao Zhigang Yao Cong Zhang Kai Wan Min Bao Ruixiang Li Maochong Shi 《Ocean Science Journal》2017,52(1):11-30
The characteristics and dynamical mechanism of summer-time coastal current over the North South China Sea shelf have been investigated based on a high resolution unstructuredgrid finite volume community ocean model (FVCOM). Modeldata comparison demonstrates that the model describes and explains well the coastal dynamics over the North South China Sea shelf. The coastal current on the North South China Sea shelf is greatly influenced by monsoon and the freshwater discharge of the Pearl River. Strong southwesterly wind drives the coastal current northeastward. However, under weak southwest monsoon, the coastal current west of the Pearl River estuary (PRE) advects toward the southwest, and splits into two parts when reaching east of the Qiongzhou Strait, with one branch entering the Gulf of Tonkin through the Qiongzhou Strait, transporting low salinity water into the Gulf of Tonkin, and the other part flows cyclonic and interacts with the northeastward current around southeast of Hainan Island, forming a cyclonic eddy east of the Qiongzhou Strait. A variety of model experiments focused on freshwater discharge, wind forcing, tidal rectification, and stratification are performed to study the physical mechanism of the southwestward coastal current which is usually against the summer wind. Process-oriented experiment results indicate that the southwest monsoon and freshwater discharge are important factors influencing the formation of southwestward coastal current during summer. 相似文献
4.
自1950年以来,长江入海输沙量呈阶段性减少趋势;作为长江远端泥,长江入海输沙量的“减沙”效应在浙闽沿岸泥质区是否有相应的沉积信号?若有,该如何进行提取和解译?为探讨以上问题,在浙闽沿岸泥质区采集柱状样5根,进行了高分辨率(2 mm)的粒度测试,并通过端元分析手段分离出4个端元。结合研究区物源及水动力的空间差异,发现各端元有其特定的指示意义:EM1组分(众数粒径约为2 μm)为长江来源的极细粒物质;EM2组分(众数粒径约为10 μm)主要为长江及浙闽沿岸中小河流的细颗粒物质,但以长江为主;EM3组分(众数粒径约为80 μm)主要为台湾暖流带来的较粗粒物质;EM4组分(众数粒径约为200 μm)为长江输运的粗颗粒物质。进一步分析发现,EM1组分对长江入海输沙量的阶段性减少有较好的响应关系:由浙闽泥质区北部至南部响应强度依次降低;在响应时间上存在滞后现象,且从北到南滞后时间增加,由北部的4~6年增加至南部的10~14年。总体来看,细颗粒组分更能反映长江流域变化信息,且泥质区的不同位置对流域变化信息的响应强度差异显著。 相似文献
5.
东北季风期台湾海峡的逆温现象 总被引:3,自引:1,他引:2
利用2006-2008年3个航次水文资料,结合日本海洋数据中心(JODC)的历史温度数据分析了东北季风期台湾海峡的逆温现象。结果显示,除台湾浅滩及海峡西岸浅水区外,几乎整个台湾海峡皆有逆温现象。逆温幅度和发生频率在海峡西部较高,海峡东部及粤东近海较低。逆温层上界深度春季较秋、冬季深,逆温频发区(发生频率大于60%)随着季节南北向移动,秋季频发区的最南端位于厦门近海,冬季扩展至台湾浅滩北部,春季回退至平潭近海。分析表明,浙闽沿岸水随季节南北向伸缩导致了逆温频发区的同步移动。除了季节变化外,逆温现象在2006年和2007年冬季有显著差异,2006年逆温仅出现在海峡西部近岸海域,2007年扩展至海峡东部且向南伸至粤东近岸,浙闽沿岸水的横向伸缩是造成此差异的主因。 相似文献
6.
We have constructed a fine-resolution model with realistic bathymetry to study the spatial and temporal variations of circulation in the Taiwan Strait (TS). The TS model with a resolution of 3~10 km derives its open boundary conditions from a larger-scale model. The QSCAT/NCEP winds and AVHRR SST provide forcing at the sea surface. Because of the high resolution in model grids and forcing, the model achieves a previously unavailable level of agreement with most observations. On biweekly time scales surface-trapped current reversals often lead to Strait transport reversals if the northeasterly wind bursts in winter are sufficiently strong. On seasonal time scales the northward current is the strongest in summer since both summer monsoon and pressure gradient force are northward. The summer northward current appears to be relatively unimpeded by the Changyun Rise (CYR) and bifurcates slightly near the surface. With the arrival of the northeast monsoon in fall, downwind movement of China Coastal Water (CCW) is blocked by the northward current near 25.5°N and 120°E. In winter, the northward current weakens even more as the northeasterly monsoon strengthens. The CCW moves downwind along the western boundary; the CYR blocks part of the CCW and forces a U-shaped flow pattern in the northern Strait. Past studies have failed to reveal an anticyclonic eddy that develops on the northern flank of CYR in winter. On interannual time scales a weakened northeast monsoon during El Niño reduces advection of the cold CCW from the north and enhances intrusion of warm water from the south, resulting in warming in the TS. 相似文献
7.
A three-dimensional numerical model is developed and used to study the coastal upwelling processes and corresponding seasonal changes in the sea level along the west coast of India. The upwelling and associated sea level variations are seen as a response of coastal ocean to pure wind stress forcing. The model is designed to represent coastal ocean physics by resolving surface and bottom Ekman layers as realistically as possible. The prognostic variables are the three components of the velocity field, temperature, salinity and turbulent energy. The governing equations together with their boundary conditions are solved by finite-difference techniques. Experiments are performed to investigate sea level fluctuations associated with the thermal response and alongshore currents of the coastal waters. The model is forced with mean monthly wind stress forcing of January, May, July and September representing northeast monsoon and different phases of the southwest monsoon. It is known from the observational study that the upwelling process reaches to the surface waters by May along the coastal waters of the extreme southwest peninsular region. The process is more intense in July compared to May and September and its strength decreases from south to north. However, during the northeast monsoon season, which is represented by January wind stress forcing in the model, downwelling is simulated along the coast. The model simulations of the coastal response are compared with the observations and are found to be in good agreement. The maximum computed vertical velocity of about 2.0 ×10 -3 cm s -1 is predicted in July in the southern region off the coast. 相似文献
8.
A three-dimensional numerical model is developed and used to study the coastal upwelling processes and corresponding seasonal changes in the sea level along the west coast of India. The upwelling and associated sea level variations are seen as a response of coastal ocean to pure wind stress forcing. The model is designed to represent coastal ocean physics by resolving surface and bottom Ekman layers as realistically as possible. The prognostic variables are the three components of the velocity field, temperature, salinity and turbulent energy. The governing equations together with their boundary conditions are solved by finite-difference techniques. Experiments are performed to investigate sea level fluctuations associated with the thermal response and alongshore currents of the coastal waters. The model is forced with mean monthly wind stress forcing of January, May, July and September representing northeast monsoon and different phases of the southwest monsoon. It is known from the observational study that the upwelling process reaches to the surface waters by May along the coastal waters of the extreme southwest peninsular region. The process is more intense in July compared to May and September and its strength decreases from south to north. However, during the northeast monsoon season, which is represented by January wind stress forcing in the model, downwelling is simulated along the coast. The model simulations of the coastal response are compared with the observations and are found to be in good agreement. The maximum computed vertical velocity of about 2.0 2 10 -3 cm s -1 is predicted in July in the southern region off the coast. 相似文献
9.
2006年9月南海北部表层温盐场的走航观测 总被引:1,自引:0,他引:1
通过2006年9月南海北部开放航次的走航观测,得到了该海区多个断面的表层温度、盐度分布曲线.QuikScat海面风场资料显示观测期间处于西南季风向东北季风的转换阶段,走航观测所得的温、盐资料显示出在这一季风转换的特殊阶段该海区表层的水文特征.珠江口冲淡水的扩散范围在季风转向前后有显著的变化,低盐的冲淡水在西南季风阶段向珠江口外海区的东南方延伸较远,而在东北季风阶段则受珠江径流量、南海北部表层环流等因素的影响收缩至珠江口附近.闽南近岸和台湾浅滩南部表层具有低温高盐特征,但CTD资料表明台湾浅滩区域存在上升流,结合风场资料,可证实观测期间此处的上升流由海流-地形因素所造成. 相似文献
10.
根据径流量,1999年和2006年夏季的长江分别处于显著洪季和旱季.此期间的月平均风向也有显著区别.根据同期的海洋现场观测:相对1999年8月,2006年同期的长江口以东、以南毗邻水域表层盐度显著较高,而在长江口东北部海域则相对偏低;长江口附近海域的底层盐度有所偏高,但在浙江中南部沿海底层盐度则相对偏低.利用Regional Ocean Modelling Systems数值模式,对1999年和2006年实际的径流量、风场和黑潮及其分支变化等3个因素对长江冲淡水扩展的影响进行了一系列模拟试验和对比.对比试验表明:相对1999年8月,2006年夏季长江流量大幅度减小是长江口毗邻海域表层盐度升高的主要原因;风场是导致长江冲淡水相对偏北,并使长江口北部出现表层盐度负异常的主要因素;黑潮及其分支在东海北部入侵相对增强、在东海南部入侵相对减弱,使长江口南部表层盐度正异常海域扩大,并促使长江淡水向江口北部扩散增强、而向东部扩散减弱.长江口毗邻海域环流和水团的变化可能对夏季低氧区位置变化产生一定影响. 相似文献
11.
孟加拉湾上层环流研究综述 总被引:2,自引:0,他引:2
综述了孟加拉湾上层环流研究的主要成果并指出,研究海区环流与季风转换不完全同步。在西南季风期间,南、北海区各有一气旋式环流;在秋季季风过渡期间,出现海湾尺度的气旋式环流;在东北季风期间,气旋式环流减弱北移,南部则为一反气旋式环流控制;春季与秋季的情形相反,整个湾出现一海湾尺度的反气旋式环流。研究海区环流的变异主要受季风、赤道远地作用和浮力通量等复杂外源作用的影响。东印度沿岸流的季节变化与季风转换也不同步,局地风、内部Ekman抽吸、远地沿岸风及赤道远地作用的影响对沿岸流周年变化有重要作用。孟加拉湾上层环流年际变化显著,此年际变化主要受赤道风场的影响。 相似文献
12.
Circulation of the East China Sea,a numerical study 总被引:4,自引:0,他引:4
Shenn-Yu Chao 《Journal of Oceanography》1990,46(6):273-295
A three-dimensional, primitive-equation model is developed to study how the Kuroshio, the monsoon, the Yangtze River outflow and the buoyancy forcing from the South China Sea affect the circulation of the East China Sea. It is found that the Kuroshio water usually intrudes into the East China Sea from both sides of Taiwan Island. Winter winds enhance the Kuroshio intrusion from northeast of Taiwan, but weaken it from the Taiwan Strait. Summer winds act in the opposite way. The increased presence of the Kuroshio water in the East China Sea in winter can be largely attributed to the shoreward surface Ekman drift associated with the northerly wind. In summer, the-shaped plume emanating from the Taiwan Strait is, to a large extent, produced by the buoyancy forcing from the South China Sea.In summer, the bimodal distribution of the Yangtze River outflow is initially produced by the upwelling-favorable wind. Away from the Yangtze River, the far-field dispersal of the fresher water depends on the strength of the Kuroshio. A stronger Kuroshio enhances the seaward dispersal of the northern branch of the Yangtze outflow north of Taiwan, but reduces the southward penetration of the southern branch. In winter, downwelling-favorable winds confine the Yangtze River outflow to a narrow band forming nearshore coastal jet penetrating southward. The northern tip of Taiwan acts as a conduit, channeling the seaward dispersal of the fresher water. The model results interpret the observed circulation patterns. 相似文献
13.
为考察长江三峡工程对河口区生态环境的影响,有必要探讨长江径流量的季节变化对河口区及口外陆架区流场结构的影响。在“长江三峡工程对长江口区流场的影响”的一文(本集)中,作者己着重探讨了三峡工程的流量调节方案将给长江口区流场带来的可能影响。本文试图从长江径流量的季节变化来分析长江口外陆架海域海流结构的季节变化,从而为三峡工程流量调节方案的设计提供某些依据。
关于长江口区及其邻近陆架海域的海流结构问题,根据实测海流资料所作的分析,迄今为止,主要限于洪水季节(即夏季)(乐肯堂,1987,1986,1984;赵保仁,1982;上海航道局设计研究所,1978;中国科学院海洋研究所,1977;华东师范大学地理系河口海岸研究室,1975,1973; Le Kentang,1986;Cannon, et al. , 1983; Beardsley et al.,1983)。长江口区枯水季节(冬季)的海流结构曾已讨论(Le Kentang, 1988)。至于春、秋两季,迄今尚未见有专题论述。本文将根据已收集到的实测余流资料(其中包括1959-1976年的资料,1980-1981年间的中美联合考察资料和1985-1986年的专题调查资料),结合有关的水文观测资料,对本区各个季节余流的结构作一初步的分析。 相似文献
14.
15.
长江口海域温、盐度分布的基本特征和上升流现象 总被引:1,自引:0,他引:1
长江口位于黄海和东海的分界处。1985年8月至1986年10月对长江口海区进行了水文调查,调查范围为124°E以西,30°45''N以北,32°N以南的黄海和东海区域(图1)。
本海区属中纬度季风区,水深一般不超过50m,气象因素对水文要素的影响很大。冬季盛行偏北风,西伯利亚的干冷气流频频南下,因海面冷却和蒸发造成的垂直对流可直达海底。夏季盛行偏南风,并常有台风侵扰。
长江径流量十分充沛,每年约有9240亿立方米的淡水人海,约占进入黄海、东海的径流量的80%。长江径流量的季节变化十分显著,5-10月径流量约占全年总径流量的71%。充足的淡水入海和海面的增温影响,使调查海区水体在夏季明显分层,并形成强大的淡水舌。特别令人感兴趣的是此淡水舌不是沿长江入海口门的方向指向东南,而是经常转向东北方向,并且转角的大小随着径流量的增大而增大。
长江口区的潮流比较大,潮混合对这里的水文要素的垂直和水平分布有重要影响。长江口是部分混合型即B型为主的河口(沈焕庭等,1986) ,发达的潮混合和充沛的径流输入,两者相互作用,使得河口区的盐度垂直分布有时呈垂直均匀状态,有时呈层化状态。
长江口海区南部有台湾暖流北上,其延续体可越过长江口到达32°N以北海区。长江口北面有苏北沿岸流和黄海沿岸流南下。北上的台湾暖流和南下的黄海沿岸流和苏北沿岸流同长江冲淡水相互交汇、混合,对长江口区的水文要素分布、变化有重要影响。
以下我们根据1985年8月至1986年8月调查所得资料和部分历史资料,对长江口海区水文要素的基本特征作一扼要的记述。 相似文献
16.
A large area hypoxia has been already reported respectively by two interdisciplinary surveys off the Changjiang Estuary since summer of 1999 and 2006. The hypoxic zone shows distinct year-to-year variations. Observed oceanographic data are first analysized and reveal a big difference for the Changjiang Diluted Water (CDW) between these two periods. These great changes are related to the tremendous reduction of the freshwater discharge and variations of wind fields between these two years. It is also found that the monthly mean intrusion of Kuroshio and its branches has increased in the northern East China Sea (ECS), but decreased in the southern ECS in August of 2006 as compared with 1999 on the base of general circulation models. Then, the Regional Ocean Modelling Systems is applied to the East China Sea to evaluate the contributions and relative importance of impacts from the river discharge, wind forcing and open boundary data. Our simulations reproduce the phenomena that more fresh water extends northeastward in 2006 and forms a negative SSS anomaly to the northeast of the river mouth as compared with 1999, which is consistent with observations. The five group numerical tests suggest that the wind forcing dominates the CDW variations followed by the Kuroshio and its branches. The study implies important roles played by hydrodynamic processes on the variability of hypoxic zone in the study areas. 相似文献
17.
长江口及邻近海域细颗粒沉积物中重金属的空间分布及沉积通量 总被引:4,自引:0,他引:4
长江每年输送大量的泥沙进入东海,其中细颗粒沉积物具有搬运距离远、扩散范围大的特点,成为示踪河口及近海沉积物源汇过程的良好载体。本文基于采自长江口及邻近海域的44个表层沉积物样品,分析了细颗粒组分中重金属的空间分布和沉积通量,探讨了重金属来源和搬运沉积过程。研究表明:长江口及邻近海域细颗粒沉积物中Cu、Cr、Ni、V和Zn含量、沉积通量的空间分布具有高度的相似性,总体表现为长江口及浙闽沿岸高,向外急剧降低;该区细颗粒沉积物中的重金属主要来自长江,入海后向两个方向扩散,其一为向西南方向扩散,沉积于内陆架泥质区;其二是向东的跨陆架输送,沉积于长江冲淡水影响的海域。从长江口向西南方向的输送和沉积是长江入海重金属最重要的汇。 相似文献
18.
于2014年3月对长江口及邻近海域的表层沉积物进行了高分辨率采样,分析了沉积物粒级组成、比表面积、总有机碳含量及其稳定碳同位素组成(δ13C)、正构烷烃及其相关分子指标,讨论了此区域沉积有机碳和正构烷烃的高分辨分布特征,并结合基于主成分分析?蒙特卡洛模拟的三端元混合模型,对沉积有机碳的来源进行了定量解析。结果表明,长江口及其邻近海域表层沉积物中总有机碳含量为0.45%±0.16%,近岸泥质区总有机碳含量较高,外海砂质区含量较低。总正构烷烃(C14?C35)的绝对含量和相对于总有机碳的含量分别为(1.42±0.73) μg/g和(0.34±0.21) mg/g。泥质区以长链正构烷烃占优势,具有较强的奇碳优势;砂质区以短链正构烷烃占优势,且具有一定的偶碳优势。长江输入、老黄河口输入、闽浙沿岸小型河流输入和水动力分选等因素制约了正构烷烃的输运和分布特征。模型结果显示此区域沉积有机碳来自海源、土壤和高等植物的混合输入,其中以海源为主,其贡献为42.70%±18.18%,由陆地向外海贡献逐渐升高,其次是土壤和高等植物,其贡献分别为28.99%±15.37%和28.31%±17.12%。在水动力分选作用的影响下,两种陆源有机碳在入海之后的输运过程中存在明显的分异,土壤有机碳主要与细颗粒物结合,并沿闽浙沿岸向南输运,而高等植物来源有机碳则在长江口存在东北方向的输运。 相似文献
19.
Analyzing intraannual variations in the energy characteristics of circulation in the Black Sea 总被引:1,自引:0,他引:1
The energy characteristics of circulation in the Black Sea have been numerically analyzed for 2006. The annually and seasonally averaged integral components of the budget of both kinetic and potential energies are considered. It is shown that, over the period under study, wind forcing, buoyancy force, and friction are the main factors determining variations in the mechanical energy of the Black Sea. During the cold months, wind forcing maximally contributes to the kinetic energy. In spring, the contribution made by buoyancy force is dominant. The values of buoyancy force are maximum within the upper quasi-homogeneous layer during the warm season and on horizons, where the waters of the cold intermediate layer are concentrated, during the fall–winter season. 相似文献