上升流辐散驱动的东海大陆坡槽尺度斜坡逆流

IF 3.3 2区 地球科学 Q1 OCEANOGRAPHY
Xuan Cui, Dezhou Yang, Arthur J. Miller, Baoshu Yin, Jiayan Yang
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引用次数: 0

摘要

观测发现,在中国东海(ECS)大陆坡的多个位置,黑潮下方存在向西南流动的持续斜坡逆流(SCCs)。目前还不清楚这些洋流是局部环流特征,还是冲绳海槽(OT)中海槽尺度环流系统的一部分。我们利用高分辨率模式模拟和物理解释证明,沿 ECS 大陆坡确实存在一个潜在的连续海槽尺度 SCC,该 SCC 与整个 OT 的气旋环流有关。拉格朗日漂流物的轨迹和被动示踪剂的时变分布说明了深层 OT 环流的详细特征。ECS 中的 SCC 具有微弱而持久的特点,通常位于 26.6-27.3 kg m-3 等压层的狭窄斜坡区域。其特征速度约为 O-(1) cm s-1。分析和实验表明,上涌气流在 SCC 层(26.6-27.3 σθ 表面)的发散引起了横向潜在涡度输送,最终推动了深层气旋环流。此外,SCC 还与黑潮的陆上侵入有密切联系,尤其是在台湾岛东北部。SCC 可能在热量和营养物质的输送以及调节深层 OT 内的沉积物分布方面发挥着重要作用。这一机制为解释半封闭边缘海中暗流的存在提供了新的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Trough-Scale Slope Countercurrent Over the East China Sea Continental Slope Driven by Upwelling Divergence

Observations have revealed the existence of persistent slope countercurrents (SCCs) that flow southwestward beneath the Kuroshio Current at several locations over the East China Sea (ECS) continental slope. It was not clear whether these flows are localized circulation features or segments of a trough-scale circulation system in the Okinawa Trough (OT). We demonstrate that there indeed exists a potentially continuous trough-scale SCC along the ECS slope that is associated with an OT-wide cyclonic circulation using high-resolution model simulations and physical interpretations. The detailed features of the deep OT circulation are illustrated by the trajectories of the Lagrangian drifters and the time-varying distributions of passive tracers. The SCC in the ECS is characterized by its weak yet persistent nature, typically located in narrow sloping regions at the isopycnal layer of 26.6–27.3 kg m−3. It exhibits a characteristic speed of approximately O-(1) cm s−1. Analyses and experiments suggest that the divergence of upwelling in the SCC layer (26.6–27.3 σθ surface) gives rise to lateral potential vorticity transport, ultimately driving the deep cyclonic circulation. Furthermore, the SCC also displays a substantial connection with the onshore intrusion of the Kuroshio Current, particularly to the northeast of Taiwan Island. The SCC may potentially play a crucial role in the transport of heat and nutrients, as well as in regulating sediment distributions within the deep OT. This mechanism offers fresh insights into explaining the presence of undercurrents in semi-enclosed marginal seas.

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来源期刊
Journal of Geophysical Research-Oceans
Journal of Geophysical Research-Oceans Earth and Planetary Sciences-Oceanography
CiteScore
7.00
自引率
13.90%
发文量
429
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