Kuroshio path variability inferred from satellite-derived sea surface topography in the northwestern Pacific

IF 11.1 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Ying-Chih Fang , Wei-Teh Li , Shao-Hua Chen
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Abstract

The Kuroshio has a fundamental impact on the regional oceanography of the northwestern Pacific. But identification of the Kuroshio path (KP), an abstraction of the course along which the Kuroshio mainstream moves, has not yet been established in a systematic manner. We optimally track the KP and study its variability in the northwestern Pacific south of ∼31°N, where eddy activity is rich. An automatic contour method based on maximum surface geostrophic velocity along a given satellite-derived dynamic topographic isoline is applied and its performance is evaluated. Our results are robust and can be further used to derive kinematical, statistical, and spectral properties of the flow field of the Kuroshio upstream. We improve the identification method by tracing two separate KPs in different subdomains. The existence of an alignment or mismatch of these two retrieved KPs hints at the arrival of an approaching eddy. The highly variable and distorted KP east of Luzon Strait and Taiwan is due to eddy impingement. Most of the variability along the KP stems from energy with time scales of ∼30–200 days and 1 year. A more consistent KP is seen north of ∼26°N, with increasing surface currents of up to ∼1 m s−1 before entering through the Tokara Strait. Such regional differences result from the various impacts of impinging mesoscale eddies on the Kuroshio, mainly due to blockage by the Ryukyu Islands. Our optimally determined KP is in line with the historical shipborne subsurface velocity measurements revealing the Kuroshio velocity core and observations of strong surface currents of > ∼0.5 m s−1 by shore-based high-frequency radar (HFR) from locations along the east coast of Taiwan. Supportive evidence of concurrent KP distortion shows that HFR-derived vortex-like flow patterns are related to mesoscale eddies impinging from regions east of the radar footprint. Our work has value as a supplement to the data from radar operational routines, and will help interpret and diagnose these complicated HFR observations east of Taiwan.
从西北太平洋卫星海面地形推断出的黑潮路径变化
黑潮对西北太平洋的区域海洋学有着根本性的影响。但是,黑潮路径(KP)是对黑潮主流移动路线的抽象,目前还没有系统地确定黑潮路径。我们对 KP 进行了最佳跟踪,并研究了它在漩涡活动丰富的北纬 31 度以南西北太平洋的变化情况。我们采用了一种自动等值线方法,该方法基于沿给定卫星衍生动态地形隔离线的最大表面地转速度,并对其性能进行了评估。我们的结果非常可靠,可进一步用于推导黑潮上游流场的运动学、统计学和频谱特性。我们通过在不同子域追踪两个独立的 KPs 来改进识别方法。这两个检索到的 KP 存在对齐或不匹配的情况,暗示着一个正在接近的漩涡的到来。吕宋海峡和台湾以东高度变化和扭曲的 KP 是漩涡撞击造成的。KP沿线的大部分变化来自时间尺度为30-200天和1年的能量。北纬 26°以北的金伯利进程较为一致,在进入托卡拉海峡之前,表层洋流不断增加,最高可达 1 米/秒。这种区域差异是由于中尺度涡流对黑潮的各种冲击造成的,主要是由于琉球群岛的阻挡。我们优化确定的 KP 与揭示黑潮速度核心的历史船载次表层速度测量结果以及台湾东海岸沿岸高频雷达(HFR)观测到的 > ∼0.5 m s-1 强表层流一致。与此同时,KP 扭曲的支持性证据表明,HFR 衍生的类似涡旋的流动模式与从雷达足迹以东区域冲击的中尺度涡流有关。我们的工作是对雷达运行例行数据的补充,将有助于解释和诊断台湾以东这些复杂的高频观测数据。
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来源期刊
Remote Sensing of Environment
Remote Sensing of Environment 环境科学-成像科学与照相技术
CiteScore
25.10
自引率
8.90%
发文量
455
审稿时长
53 days
期刊介绍: Remote Sensing of Environment (RSE) serves the Earth observation community by disseminating results on the theory, science, applications, and technology that contribute to advancing the field of remote sensing. With a thoroughly interdisciplinary approach, RSE encompasses terrestrial, oceanic, and atmospheric sensing. The journal emphasizes biophysical and quantitative approaches to remote sensing at local to global scales, covering a diverse range of applications and techniques. RSE serves as a vital platform for the exchange of knowledge and advancements in the dynamic field of remote sensing.
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