Circulation Around Luzon Strait in September as Inferred from CTD,Argos and Argo Measurements and a Generalized Topography-Following Ocean Model     

《大气与海洋》2012,50(4):40-58

The hydrography, wind, Argos and Argo measurements in the areas surrounding Luzon Strait were collected. Based on the hydrographic data obtained during September 1994, the improved Princeton Ocean Model using a generalized topography-following coordinate system together with a modified inverse method was applied to study the circulation in September. Observations and the diagnostic simulation produce a consistent circulation pattern, and the main dynamical features can be summarized as follows. (1) The Kuroshio has two branches with the main Kuroshio existing above 800 m depth and the western part existing above 400 m depth. The western branch of the Kuroshio leaves the main current near 20.5°N, then flows northwestward through Luzon Strait and finally flows out of the northern boundary southwest of Taiwan, consistent with the trajectory of Argos drifters. (2) The non-linear term is important and cannot be neglected in the momentum equations in the northern part of Luzon Strait under the baroclinicity field. Using non-linear dynamics, the westward intrusion of the Kuroshio into the northern part of Luzon Strait is more curved than when using linear dynamics. However, the non-linear term is smaller and so negligible around Luzon Strait under the homogeneous density field. (3) In the area from 117°E to 119°E and from 20.2°N to 21.7°N, an anticyclonic eddy appears east of Dongsha Islands. (4) At depths above 400 m, the circulation is mainly dominated by the basin-scale cyclonic gyre. (5) In the computational domain west of 121°E, the circulation below 800 m is mainly dominated by the basin-scale anticyclonic gyre. (6) The South China Sea water flows eastward across Luzon Strait in the middle layers, then turns cyclonically, finally flowing northward into the region east of Taiwan Island, which is qualitatively in agreement with the trajectories of Argo floats at about 1000 m depth in the area east of 121°E.

RÉSUMÉ?[Traduit par la rédaction] Nous avons rassemblé l'hydrographie, le vent, les Argo et les mesures Argo dans les régions avoisinant le détroit de Luçon. Sur la base des données hydrographiques relevées durant le mois de septembre 1994, nous avons appliqué le modèle océanique amélioré de Princeton utilisant un système de coordonnées « suivant le terrain » généralisé de pair avec une méthode inverse modifiée pour étudier la circulation en septembre. Les observations et la simulation diagnostique produisent une configuration de circulation cohérente dont on peut résumer comme suit les principales caractéristiques dynamiques. (1) Le Kuroshio possède deux branches : le Kuroshio principal existant au-dessus d'une profondeur de 800 m et la partie ouest existant au-dessus d'une profondeur de 400 m. La branche ouest du Kuroshio quitte le courant principal aux environs de 20,5°N et se dirige vers le nord-ouest à travers le détroit de Luçon pour finalement franchir la limite nord du détroit au sud-ouest de Taïwan, ce qui correspond à la trajectoire des bouées dérivantes Argos. (2) Le terme non linéaire dans les équations est important et ne peut pas être considéré négligeable de quantité de mouvement dans la partie nord du détroit de Luçon dans le champ de baroclinité. Lorsqu'on utilise la dynamique non linéaire, l'intrusion vers l'ouest du Kuroshio dans la partie nord du détroit de Luçon est plus incurvée que lorsqu'on utilise la dynamique linéaire. Cependant, le terme non linéaire est plus petit et donc négligeable autour du détroit de Luçon dans le champ de densité homogène. (3) Dans la région allant de 117°E à 119°E et de 20,2°N à 21,7°N, un remous anticyclonique apparaît à l'est des îles Dongsha. (4) Aux profondeurs inférieures à 400 m, la circulation est principalement dominée par le gyre cyclonique à l’échelle du bassin. (5) Dans le domaine de calcul à l'ouest de 121°E, la circulation sous 800 m est principalement dominée par le gyre anticyclonique à l’échelle du bassin. (6) Les eaux de la mer de Chine méridionale s’écoulent vers l'est à travers le détroit de Luçon dans les couches intermédiaires, puis tournent de façon cyclonique pour finalement s’écouler vers le nord dans la région à l'est de l’île Taïwan, ce qui, qualitativement, s'accorde avec la trajectoire des flotteurs Argo à environ 1000 m de profondeur dans la région à l'est de 121°E.  相似文献   

Air–sea interaction over ocean fronts and eddies   总被引：1，自引：0，他引：1  

R.J. Small  S.P. deSzoeke  S.P. Xie  L. O&#x;Neill  H. Seo  Q. Song  P. Cornillon  M. Spall  S. Minobe 《Dynamics of Atmospheres and Oceans》2008,45(3-4):274

Air–sea interaction at ocean fronts and eddies exhibits positive correlation between sea surface temperature (SST), wind speed, and heat fluxes out of the ocean, indicating that the ocean is forcing the atmosphere. This contrasts with larger scale climate modes where the negative correlations suggest that the atmosphere is driving the system. This paper examines the physical processes that lie behind the interaction of sharp SST gradients and the overlying marine atmospheric boundary layer and deeper atmosphere, using high resolution satellite data, field data and numerical models. The importance of different physical mechanisms of atmospheric response to SST gradients, such as the effect of surface stability variations on momentum transfer, pressure gradients, secondary circulations and cloud cover will be assessed. The atmospheric response is known to create small-scale wind stress curl and divergence anomalies, and a discussion of the feedback of these features onto the ocean will also be presented. These processes will be compared and contrasted for different regions such as the Equatorial Front in the Eastern Pacific, and oceanic fronts in mid-latitudes such as the Gulf Stream, Kuroshio, and Agulhas Return Current.  相似文献   

东海黑潮暖舌的演变及其对我国气温的影响   总被引：1，自引：1，他引：0  

殷明  肖子牛  黎鑫  李崇银 《气候与环境研究》2016,21(3):333-345

利用高分辨率的海温分析资料模式资料,分析了黑潮暖舌与我国气温的关系,初步探讨了太平洋年代际振荡(PDO)等造成黑潮暖舌变化的可能原因。结果表明,冬季和春季东海黑潮暖舌存在明显的年际和年代际变化。暖舌在1996/1997年发生了一次突变,此前暖舌处在偏冷的状态,之后转为偏暖的状态。我国冬季和春季气温存在一定的年代际变化,1997年之后,冬季除东北和新疆外,气温有所偏高,而春季气温全国表现为一致的显著偏高。冬季和春季气温对黑潮暖舌存在邻(域)响应。冬季东海黑潮暖舌指数与冬季我国东部气温存在正相关,并且这一相关性能够延续到次年春季。冬季黑潮暖舌指数与我国4月海陆热力差异指数也存在显著的正相关。当冬季暖舌偏强(弱)时,4月海陆热力差异指数偏高(低),即东亚地区海陆热力差异偏大(小)。春季黑潮暖舌指数与春季我国中部及南方地区气温也存在正相关,当春季黑潮暖舌偏强(弱)时,上述地区气温将偏高(低)。PDO和黑潮暖舌之间的相互作用存在一个反馈机制。西风的增强,可通过使海洋向大气释放热量增加和向南的埃克曼(Ekman)输送,降低北太平洋中部的SST,而这一地区SST的降低对应着PDO的暖位相。增强的负风应力旋度在北太平洋副热带流涡中强迫出的向南斯维尔德鲁普(Sverdrup)流也偏强,而向北流动的东海黑潮的增强正是补偿了这一向南的海流。黑潮增强后经过两个月将大量热量输送至北太平洋中部,增强了这一地区的SST,而这对应着PDO的冷位相。  相似文献   

黑潮延伸体海域典型涡旋的次中尺度特征分析*     

张旭  经志友  郑瑞玺  黄小龙  曹海锦 《热带海洋学报》2021,40(6):31-40

本文基于卫星遥感资料和高分辨率ROMS(Regional Ocean Modeling System)数值模拟结果, 对黑潮延伸体海域典型中尺度涡旋的次中尺度特征进行了探讨。卫星观测和模拟结果显示, 黑潮延伸体涡旋海域伴随着活跃的次中尺度现象。涡旋演变与多尺度能量分析结果表明, 涡旋海域次中尺度动能的强弱与涡旋海域地转流动能有着密切联系, 锋生可能是涡旋边缘次中尺度动能增强的重要机制。次中尺度现象在中尺度涡旋海域具有沿地转流方向的复杂涡丝状结构特征, 意味着涡旋边缘较强的水平浮力梯度和地转流侧向剪切为次中尺度过程形成与发展提供了有利条件。此外, 垂向结构分析表明, 次中尺度过程能引起较大的垂向速度, 最大可达100m·day^-1, 该垂向速度可以影响至混合层下200m深度处, 对海洋内部的垂向物质能量交换、海—气相互作用等有着重要的影响。  相似文献   

东海北部小型底栖动物群落对径流及黑潮暖流入侵的响应   总被引：1，自引：1，他引：0  

刘清河  马林  李新正 《海洋学报》2020,42(2):52-64

为探究小型底栖动物群落在东海北部及其临近海域的分布规律，及其对环境因子的响应，于2016年9月和12月，对研究海域共计20个站位的小型底栖动物和环境因子进行了取样调查。调查结果显示，研究海域内共鉴定出小型底栖动物类群16个，其中海洋线虫为绝对优势类群，其他优势类群主要包括桡足类、动吻类和多毛类。9月航次小型底栖动物平均丰度为(1 758±759)个/（10 cm2），线虫占95.6%；平均生物量为(1 216.4±464.7) μg/(10 cm2)(干重)，线虫占55.26%。12月航次平均丰度为(2 011±1 471)个/(10 cm2)，线虫占95.6%；平均生物量为(1 143.0±755.0)μg/(10 cm2)(干重)，线虫占67.28%。聚类分析结果显示，小型底栖动物群落主要可以划分为近岸和外海两个组，其中近岸组小型底栖动物丰度显著高于外海站位。但在各断面分布上，绝大多数站位小型底栖动物丰度最高值均出现在60 m等深线附近，并且该水深处站位的温度和盐度数值均表现出黑潮水的特征。黑潮近岸分支对东海陆架入侵是导致小型底栖动物分布差异的重要原因，小型底栖动物在60 m等深线附近具有的高丰度值可作为其对黑潮入侵的响应。推测，黑潮入侵所导致的水体初级生产力增加以及黑潮水所携带的溶氧可能是导致该深度处小型底栖动物丰度增加的主要原因。  相似文献   

基于HYCOM再分析数据研究琉球海流的形成与起源     

汪敏  刘昭君  朱小华  闫晓梅  张钟哲  赵瑞祥 《海洋学报(英文版)》2019,38(11):1-10

The origin of the Ryukyu Current(RC) and the formation of its subsurface velocity core were investigated using a 23-year(1993–2015) global Hybrid Coordinate Ocean Model(HYCOM) dataset. The volume transport of the RC comes from the Kuroshio eastward branch(KEB) east of Taiwan and part of the North Pacific Subtropical Gyre(pNPSG). From the surface to 2 000 m depth, the KEB(p-NPSG) transport contributes 41.5%(58.5%) to the mean total RC transport. The KEB originally forms the subsurface velocity core of the RC east of Taiwan due to blockage of the subsurface Kuroshio by the Ilan Ridge(sill depth: 700 m). Above 700 m, the Kuroshio can enter the East China Sea(ECS) over the Ilan Ridge, meanwhile, the blocked Kuroshio below 700 m turns to the right and flows along the Ryukyu Islands. With the RC flowing northeastward, the p-NPSG contribution strengthens the subsurface maximum structure of the RC owing to the blockage of the Ryukyu Ridge. In the surface layer, the pNPSG cannot form a stable northeastward current due to frequent disturbance by mesoscale eddies and water exchange through the gaps(with net volume transport into ECS) between the Ryukyu Islands.  相似文献   

南海海洋环流研究综述   总被引：18，自引：0，他引：18  

杨海军  刘秦玉 《地球科学进展》1998,13(4):364-368

综述了近二十年来南海海洋环流的主要研究成果,指出太阳辐射、季风和地形是影响南海环流的主要因素;提出了南海环流研究中应特别注意的几个关键问题,即南海环流的平均状态、南海暖流、南海中的局地涡旋、南海暖池、黑潮与南海水的交换、地形对南海环流的作用以及南海水温变化与ENSO的关系等;最后就目前研究中存在的困难提出了相应的对策。  相似文献   

夏季对马暖流区黑潮水与陆架水的相互作用──兼论对马暖流的起源   总被引：16，自引：4，他引：12  

郭炳火  李兴宰  李载学 《海洋学报》1998,20(5):1-12

根据1994年8月28日至9月7日韩国“Onnuri”号海洋调查船获得的CTD资料及在调查期间投放的11个卫星跟踪漂流浮标资料,分析研究了东海东北部黑潮水的分离及其与陆架水的相互作用,进而探讨了夏季的对马暖流的形成过程。  相似文献   

Satellite and ship observations of Kuroshio warm-core ring 93A off Sanriku, northwestern North Pacific, in spring 1997     

Sei-Ichi Saitoh  Denzo Inagake  Kousei Sasaoka  Joji Ishizaka  Yukihiro Nakame  Toshiro Saino 《Journal of Oceanography》1998,54(5):495-508

Synoptic ship and satellite observations were performed of the Kuroshio warm-core ring (KWCR) 93A and its adjacent waters, off Sanriku, northwestern North Pacific, between early April and late June 1997. The temporal and spatial distribution of chlorophylla (Chl-a) and sea surface temperature in the study area were analyzed using data from ADEOS Ocean Color and Temperature Scanner (OCTS) and NOAA Advanced Very High Resolution Radiometer (AVHRR). The objective of this study was to describe the temporal and spatial variability of the spring bloom and understand its relationship with the changes in the hydrographic structure of these waters in and around KWCR 93A. The maximum value of Chl-a concentration in the ring was less than 1 mg/m³ during April. The spring bloom in the ring occurred early in May and the relatively high maximum (>1.0 mg/m³) continued from early in May to mid-June. In late June, a ship-observed surface Chl-a concentration of less than 0.4 mg/m³ suggests that the spring bloom had already declined in and around KWCR 93A. Double spiral structures of warm and cold streamers appeared from late April to mid-May, which may have an influence on the occurrence of the spring bloom in and around the ring. In this episodic event, the warm streamer can maintain the available potential energy of the ring and the strength of upwelling around the ring. The cold streamer provided water with a high Chl-a concentration to the surface layer of the ring. In order to understand the temporal and spatial variability of Chl-a distribution in the ring, the behavior of the warm and cold streamers needs to be taken into consideration.  相似文献   

The Kuroshio East of Taiwan and in the East China Sea and the currents East of Ryukyu Islands during early summer of 1996   总被引：6，自引：0，他引：6  

Yaochu Yuan  Arata Kaneko  Jilan Su  Xiaohua Zhu  Yonggang Liu  Noriaki Gohda  Hong Chen 《Journal of Oceanography》1998,54(3):217-226

Using hydrographic data and moored current meter records and the ADCP observed current data during May–June 1996, a modified inverse method is applied to calculate the Kuroshio east of Taiwan and in the East China Sea and the currents east of Ryukyu Islands. There are three branches of the Kuroshio east of Taiwan. The Kuroshio in the East China Sea comes from the main (first) and second branches of the Kuroshio east of Taiwan. The easternmost (third) branch of the Kuroshio flows northeastward to the region east of Ryukyu Islands. The net northward volume transports of the Kuroshio through Section K₂ southeast of Taiwan and Section PN in the East China Sea are 44.4×10⁶ and 27.2×10⁶ m³s⁻¹, respectively. The western boundary current east of Ryukyu Islands comes from the easternmost branch of the Kuroshio east of Taiwan and an anticyclonic recirculating gyre more east, making volume transports of 10 to 15×10⁶ m³s⁻¹. At about 21°N, 127°E southeast of Taiwan, there is a cold eddy which causes branching of the Kuroshio there.  相似文献