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刘宝银 《中国海洋大学学报(自然科学版)》1982,(3)
我国开始接收高分辨力的气象卫星图象以来,作者曾对东海及其毗邻海区的卫片进行了分析与研究。现选用了具有季节性代表与有关季节的连续性图象,并对其进行处理、甄别、数理分析与佐证。获得了东海黑潮逐年典型月份表层温度锋解译图与表层温度场模式数据。这对认识东海黑潮区冬、春季表层温度锋的分布态势是有用的,与常规 相似文献
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利用WOA13(1955-2012年)月平均数据提取东海黑潮主轴温度锋信息,并结合海表面温度、PN断面温度结构的季节变化特征,研究东海黑潮主轴温度在垂直方向和水平方向的季节变化,探讨黑潮主轴温度锋季节变化特征,为开展黑潮相关研究提供基础。结果表明WOA13数据对东海黑潮主轴温度锋信息的提取具有较好的效果;在PN断面上,冬、春季节的流核结构最为明显;在130~170 m深度上,东海黑潮主轴温度锋具有明显的季节变化特征,并且可以明显看到黑潮大弯曲的存在;温度锋在150 m上下的深度对黑潮路径的表征较为合理。 相似文献
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海洋锋是典型的海洋中尺度现象之一。目前卫星遥感主要利用海表温度数据分析海洋锋,但由于西北太平洋海域夏季海表温度的趋同特性,不能进行有效的锋面监测;而不同水团所具有的生物光学特性往往是不同的,且不具有太阳辐射引起的显著性季节变化,因此海色资料也成为检测海洋锋的有效数据源。文中以东海黑潮为例,详细说明了基于叶绿素a浓度融合数据,采用梯度法进行海洋锋面检测的过程,通过比较不同季节不同梯度阈值得到的东海黑潮锋结果,从保持锋面的完整性及对零碎锋区的剔除效应方面,选取了不同季节较优的梯度阈值。总体来说,文中检测出的东海黑潮区域海色锋与海流黑潮强流区较吻合,12月至4月东海黑潮海色锋检测结果不如海温锋,而5-11月东海黑潮海色锋检测结果优于海温锋,特别是台湾以东黑潮区域,不论什么季节海温锋都没有体现,而海色锋始终很明显。利用文中提出的海洋锋检测算法、分析方法及选择的梯度阈值可以有效地检测东海黑潮区域的海洋锋面,结合海色锋和海温锋,可以监测分析东海黑潮强流区的时空变化。 相似文献
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利用诺阿卫星红外信息对东海黑潮表层温度锋的解译 总被引:1,自引:0,他引:1
刘宝银 《山东海洋学院学报》1982,12(3):11-20
我国开始接收高分辨力的气象卫星图象以来,作者曾对东海及其毗邻海区的卫片进行了分析与研究。现选用了具有季节性代表与有关季节的连续性图象,并对其进行处理、甄别、数理分析与佐证。获得了东海黑潮逐年典型月份表层温度锋解译图与表层温度场模式数据。 相似文献
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海洋锋是特性明显不同的两种或几种水体之间的水平分布高梯度带。海洋锋对海战场环境存在重要影响。文中基于高性能计算机平台,采用海洋动力模式和先进的数据同化技术制作的海洋数值再分析产品(China Ocean Reanalysis,CORA),研究了东中国海温度锋和盐度锋分别在表层和50 m层深度上的季节变化特征。通过分析发现温度锋在冬季主要分布在东海及台湾海峡,在夏季主要分布在渤海及黄海;春秋两季的变化介于冬夏两季之间;东海黑潮区四季皆存在温度锋。盐度锋主要存在于黄河和长江等径流入海区附近。温度锋和盐度锋的季节变化主要受气象条件、河流入海和近岸升降流季节变化的共同影响。 相似文献
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利用美国国家海洋大气管理局2007年发布的全球海域温、盐数据库资料,美国地球物理数据中心2006年发布的海底地形数据库资料以及日本海洋科学与技术机构2003年发布的1997—2002年东海地区月平均降水量资料,研究东海黑潮表层盐度的月季分布特征,并分析其影响因素。结果表明,东海黑潮表层盐度存在明显的月季变化特征。总体而言,12月至次年3月表层盐度高,6—9月表层盐度低,4、5月和10、11月为过渡阶段;表层盐度高值分布在东海黑潮主段靠近东边界一侧;6—9月入口段的表层盐度高于出口段的表层盐度,其他月份入口段的表层盐度低于出口段的表层盐度。东海黑潮表层盐度主要受表层温度、降水、径流的影响。冬、春、秋季的表层盐度分布在黑潮主段靠近陆架一侧区域受表层温度影响大;降水对东海黑潮表层盐度产生局部小范围的影响,时间主要集中在1月和6—8月份,区域分布在低纬25°N以南和30°N附近。长江冲淡水夏季对东海黑潮表层盐度的影响大于其他季节对东海黑潮表层盐度的影响,7月长江径流量达到最大值时,对应的黑潮扇形区的盐度最低。 相似文献
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本文利用近十年来获得的NOAA卫星红外影像,较为系统地分析了东海海洋锋(黑潮锋、对马暖流锋和浙江沿岸锋)的波动谱特征以及形态的演变。同时还利用浮标测流结果分析了锋面波动中的流态。分析结果表明:东海黑潮锋通常存在4~5个折叠波形,其波长平均约200km,波动随黑潮流向东北方向传播,速度约16cm/s。浙江沿岸锋的波动多呈锯齿形,其波长较短,波数多。在浙江沿岸锋波动发展过程中,其波长从开始的20~40km发展成30~60km,它们约以18cm/s的速度向东北方向传播。东海海洋锋波动演变形态复杂,其中黑潮锋的波动可能演变成锋面涡旋、暖丝和暖环。 相似文献
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本文分析了东海黑潮锋的海洋学特征,讨论了它的季节和年际变化。指出东海黑潮锋属中强度锋,为较强的水平温度梯度所标志;当锋的强度有较大的增强时,锋的位置也发生较大的迁移;锋与东海中部渔场的关系密切。 相似文献
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Study on interaction between the coastal water, shelf water and Kuroshio water in the Huanghai Sea and East China Sea 总被引:3,自引:3,他引:3
The main processes of interaction between the coastal water, shelf water and Kuroshiowater in the Huanghai Sea (HS) and East China Sea (ECS) are analyzed based on the observation and study results in recent years. These processes include the intrusion of the Kuroshio water into the shelf area of the ECS, the entrainment of the shelf water into the Kuroshio, the seasonal process in the southern shelf area of the ECS controlled alternatively by the Taiwan Strait water and the Kuroshio water intruding into the shelf area, the interaction between the Kuroshio branch water, shelf mixed water and modified coastal water in the northeastern ECS, the water-exchange between the HS and ECS and the spread of the Changjiang diluted water. 相似文献
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Surface distribution and seasonal variation of alkalinity and specific alkalinity in Kuroshio area of the East ChinaSea and their application to the water mass tracing are discussed in this paper. Results show a distinct seasonal variation of the alkalinity, which is concerned with the process of vertical mixing. Different specific alkalinity in various water masses has been found. On the basis of the difference of the specific alkalinity and the distribution of alkalinity, two water fronts in summer season, located at 27°-30°N and 124°-1 27°E, (Ⅰ), and at the northern waters about one latitude from the Taiwan Island, (Ⅱ); one in winter season at about one longitude from coast of mainland of China and 26°-30°N were found. In summer season, about 1-2 longitudes eastward shift of front (Ⅰ) is found by comparison of data in May and August. And the high alkalinity of the northern East China Sea in summer season may be caused by the Huanghe River runoff flowing southward along with the Huanghai Sea 相似文献
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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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Spring phytoplankton bloom in the fronts of the East China Sea 总被引:2,自引:0,他引:2
Frontal areas between warm and saline waters of the Kuroshio currents and colder and diluted waters of the East China Sea
(ECS) influenced by the Changjiang River were identified from the satellite thermal imagery and hydrological data obtained
from the Coastal Ocean Process Experiment (COPEX) cruise during the period between March 1st and 10th, 1997. High chlorophyll concentrations appeared in the fronts of the East China Seas with the highest chlorophyll-a concentration
in the southwestern area of Jeju Island (~2.9 mg/m3) and the eastern area of the Changjiang River Mouth (~2.8 mg/m3). Vertical structures of temperature, salinity and density were similar, showing the fronts between ECS and Kuroshio waters.
The water column was well mixed in the shelf waters and was stratified around the fronts. It is inferred that the optimal
condition for light utilization and nutrients induced both from the coastal and deep waters enhances the high phytoplankton
productivity in the fronts of the ECS. In addition, the high chlorophyll-a in the fronts seems to have been associated with
the water column stability as well. 相似文献
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As a fundamental study to evaluate the contribution of the Kuroshio to primary production in the East China Sea (ECS), we
investigated the seasonal pattern of the intrusion from the Kuroshio onto the continental shelf of the ECS and the behavior
of the intruded Kuroshio water, using the RIAM Ocean Model (RIAMOM). The total intruded volume transport across the 200m isobath
line was evaluated as 2.74 Sv in winter and 2.47 Sv in summer, while the intruded transport below 80m was estimated to be
1.32 Sv in winter and 1.64 Sv in summer. Passive tracer experiments revealed that the main intrusion from the Kuroshio to
the shelf area of the ECS, shallower than 80m, takes place through the lower layer northeast of Taiwan in summer, with a volume
transport of 0.19 Sv. Comparative studies show several components affecting the intrusion of the Kuroshio across the 200 m
isobath line. The Kuroshio water intruded less onto the shelf compared with a case without consideration of tide-induced bottom
friction, especially northeast of Taiwan. The variations of the transport from the Taiwan Strait and the east of Taiwan have
considerable effects on the intrusion of the Kuroshio onto the shelf. 相似文献
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为了研究黑潮跨过200m等深线对东海入侵的年际变化特征,本文基于ROMS(Regional Ocean Modeling System)海洋模式,对西北太平洋海域进行了高分辨率的数值模拟,模式水平分辨率高达4km,该分辨率可以很好地分辨黑潮以东区域的中尺度涡旋等过程。模式首先进行了6年的气候态模拟,然后进行了1993到2015年的后报模拟。模式很好地再现了东海陆架已知的环流结构,模拟出的对马海峡和台湾海峡的年平均流量和观测结果也比较一致。基于模式结果,利用旋转经验正交函数(REOF)的方法,对黑潮跨过200m等深线流量的年际变化进行分析。REOF的主要模态表明,黑潮跨过200m等深线对东海陆架的入侵主要发生台湾东北,并且入侵主要集中在黑潮次表层水中。主要模态的时间系数表明,黑潮入侵东海陆架的年平均流量存在一个8年的变化周期。相关性分析表明,黑潮入侵东海陆架的年际变化和太平洋年代际振荡PDO(Pacific Decadal Oscillation)指标具有显著的负相关,其相关系数达–0.63。该相关可以通过如下过程解释:PDO会导致东太平洋风应力涡度异常,由Sverdrup关系可知向赤道的体积输运也会相应地产生异常,根据质量守恒,向赤道体积输运的异常必然通过西边界流-黑潮的异常来平衡,从而导致黑潮入侵东海陆架强烈的年际变化。 相似文献
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The hydrographic surveys in an area immediately northeast of Taiwan showed that the Kuroshio surface water intruded onto the shelf in the spring and there was a thick mixed layer and weak vertical stratification in the Kuroshio at the time. During the summer season, a strong thermocline was developed in the Kuroshio and the flow shifted offshore from Taiwan in front of the continental shelf break of the East China Sea. A numerical model is used to examine the effect of this seasonal thermocline on the flow pattern of the survey area. We find that the surface strength of the disturbance above the Su-Ao ridge is closely related to the occurrence of the on-shelf intrusion of Kuroshio. The presence of a seasonal thermocline in the Kuroshio can greatly diminish this disturbance in the surface level. 相似文献
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Fei Zunle 《海洋学报(英文版)》1992,11(1):97-107
On the basis of the data obtained from the comprehensive Kuroshio surveys in 1987-1988,this paper analyses the oceanographic characteristics in the area (125°-130° E,27°-31° N) of the continental shelf edge of the East China Sea (E. C. S. ) and its adjacent waters and discusses the effects of the Kuroshio front,thermocline and upwelling of the Kuroshio subsurface water on the distribution of standing stock of phytoplankton (chlorophyll-a). The distribution of high content of chlorophylly-a has been detected at 20-50 in depth in the water body on the left side of the Kuroshio front in the continental shelf edge waters of the E. C. S. The high content of chlorophyll-a spreads from the shelf area to the Kuroshio area in the form of a tongue and connects with the maximum layer of subsurface chlorophyll-a of the Kuroshio and pelagic sea. The author considers that the formation of the distribution of high content chlorophyll-a in this area results from the bottom topography and oceanic environment and the 相似文献