Spatiotemporal characteristics of the near-surface turbulent cascade at the submesoscale in the Drake Passage

IF 2.8 2区 地球科学 Q1 OCEANOGRAPHY Journal of Physical Oceanography Pub Date : 2023-11-08 DOI:10.1175/jpo-d-23-0108.1
P. F. Tedesco, L. E. Baker, A. C. Naveira Garabato, M. R. Mazloff, S. T. Gille, C. P. Caulfield, A. Mashayek
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Abstract

Abstract Submesoscale currents and internal gravity waves achieve an intense turbulent cascade near the ocean surface (0 m – O (100) m depth), which is thought to give rise to significant energy sources and sinks for mesoscale eddies. Here, we characterise the contributions of Non-Wave Currents (NWCs; including eddies and fronts) and Internal Gravity Waves (IGWs; including near-inertial motions, lee waves and the internal wave continuum) to near-surface submesoscale turbulence in the Drake Passage. Using a numerical simulation, we combine Lagrangian filtering and a Helmholtz decomposition to identify NWCs and IGWs and to characterise their dynamics (rotational vs. divergent). We show that NWCs and IGWs contribute in different proportions to the inverse and forward turbulent kinetic energy cascades, based on their dynamics and spatiotemporal scales. Purely rotational NWCs cause most of the inverse cascade, while coupled rotational– divergent components of NWCs and coupled NWC–IGWs cause the forward cascade. The cascade changes direction at a spatial scale at which motions become increasingly divergent. However, the forward cascade is ultimately limited by the motions’ spatiotemporal scales. The bulk of the forward cascade (80 – 95%) is caused by NWCs and IGWs of small spatiotemporal scales ( L <10 km; T <6 hours), which are primarily rotational: submesoscale eddies, fronts, and the internal wave continuum. These motions also cause a significant part of the inverse cascade (30%). Our results highlight the requirement for high spatiotemporal resolutions to diagnose the properties and large-scale impacts of near-surface submesoscale turbulence accurately, with significant implications for ocean energy cycle study strategies.
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德雷克海峡亚中尺度近地表湍流级联的时空特征
亚中尺度流和内部重力波在海洋表面附近(0 m - 0 (100) m深度)形成强烈的湍流级联,被认为是中尺度涡旋的重要能量来源和汇。在这里,我们描述了非波浪流(NWCs)的贡献;包括涡旋和锋面)和内部重力波(igw);包括近惯性运动、背风波和内波连续体)到德雷克海峡近地表亚中尺度湍流。通过数值模拟,我们结合拉格朗日滤波和亥姆霍兹分解来识别nwc和igw,并表征它们的动力学(旋转与发散)。研究表明,基于它们的动力学和时空尺度,nwc和igw对逆行和正向湍流动能级联的贡献比例不同。纯旋转的nwc引起了大部分的逆级联,而nwc的旋转发散分量和nwc - igw的耦合引起了正向级联。级联在运动变得越来越分散的空间尺度上改变方向。然而,正向级联最终受到运动时空尺度的限制。大部分正向叶栅(80 - 95%)是由小时空尺度(L <10 km;t<6小时),主要是旋转的:亚中尺度涡旋、锋面和内波连续体。这些运动也引起了反级联的很大一部分(30%)。我们的研究结果强调了对高时空分辨率的要求,以准确诊断近地表亚中尺度湍流的性质和大尺度影响,这对海洋能量循环研究策略具有重要意义。
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来源期刊
CiteScore
2.40
自引率
20.00%
发文量
200
审稿时长
4.5 months
期刊介绍: The Journal of Physical Oceanography (JPO) (ISSN: 0022-3670; eISSN: 1520-0485) publishes research related to the physics of the ocean and to processes operating at its boundaries. Observational, theoretical, and modeling studies are all welcome, especially those that focus on elucidating specific physical processes. Papers that investigate interactions with other components of the Earth system (e.g., ocean–atmosphere, physical–biological, and physical–chemical interactions) as well as studies of other fluid systems (e.g., lakes and laboratory tanks) are also invited, as long as their focus is on understanding the ocean or its role in the Earth system.
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