2017-2018年哈特拉斯沿海海洋的大气强迫:PEACH计划

IF 1.9 4区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Dynamics of Atmospheres and Oceans Pub Date : 2023-06-01 DOI:10.1016/j.dynatmoce.2023.101364
John Bane , Harvey Seim , Sara Haines , Lu Han , Ruoying He , Joseph Zambon
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引用次数: 1

摘要

哈特拉斯沿海海洋位于美国48个相邻国家东海岸的中心,哈特拉斯角近海,处于一个复杂的陆地/海洋/大气区域,不同温度和盐度的主要洋流在这里交汇并相互作用,大气在大范围的时间尺度上波动,以及大气-海洋相互作用在空间和时间上都不同。墨西哥湾流通常会在这里与大陆边缘接触。来自北方和南方的大陆架洋流在这里交汇,形成了陆架水域从陆架到海洋的净输送,这些陆架水域具有重要的水特性和成分。这些陆架流和交换的两个主要驱动因素是大气和海洋墨西哥湾流。哈特拉斯沿海海洋的大气驱动是通过空气-海洋界面的表面风应力和热通量实现的。该地区的复杂性和重要性促使美国国家科学基金会在2017-2018年赞助了PEACH研究计划(PEACH:推动哈特拉斯角交换的过程)。在本文中,我们利用PEACH期间的大量观测数据来描述当时海洋的大气强迫。大气条件分为两个季节:温暖季节(5月至9月中旬),主要是温和的东北风,偶尔会有热带气旋;以及凉爽的季节(9月中旬至4月),高能温带气旋(ETC)几乎连续向东北方向穿过该地区。冷季ETC迫使该地区出现强风应力和海洋到大气的热通量事件,每次事件的时间尺度为几天。风应力波动幅度通常超过每个季节的平均应力幅度3-5倍。这些应力仅占该地区总洋流变化的40%以上,表明风是这里海洋的主要驱动力。大气-海洋热通量通常在整个温暖季节进入海洋(~100 W m-2);在凉爽的季节(约500 W m-2或更大)。本文的新结果包括:急流位置的季节内向南振荡驱动了最强的ETC(包括一个“炸弹”气旋);在PEACH之前和包括PEACH在内的41年中,经过哈特拉斯沿海海洋的大气气旋的季节平均数量和强度几乎没有长期变化。展望未来,美国国家科学基金会先锋阵列计划于2024年搬迁到哈特拉斯沿海海洋的北部,美国国家航空航天局SWOT卫星已开始其海洋地形任务,该任务在这里有一个地面轨道交叉点。
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Atmospheric forcing of the Hatteras coastal ocean during 2017–2018: The PEACH program

The Hatteras coastal ocean is centrally located along the east coast of the 48 contiguous United States, offshore of Cape Hatteras in a complex land/ocean/atmosphere region where major ocean currents of differing temperatures and salinities meet and interact, where the atmosphere fluctuates on a wide range of time scales, and where atmosphere-ocean interactions vary both spatially and temporally. The Gulf Stream current typically leaves its contact with the continental margin here. Continental shelf currents from the north and from the south converge here, resulting in a net shelf-to-ocean transport of shelf waters that carry important water properties and constituents. The two major drivers of these shelf currents and exchanges are the atmosphere and the oceanic Gulf Stream. Atmospheric driving of the Hatteras coastal ocean is through surface wind stress and heat flux across the air-sea interface. The complexity and importance of this region motivated the NSF-sponsored PEACH research program during 2017–2018 (PEACH: Processes driving Exchange At Cape Hatteras). In this paper, we utilize the substantial number of observations available during PEACH to describe the atmospheric forcing of the ocean then. Atmospheric conditions are described in terms of two seasons: the warm season (May to mid-September), with predominantly mild northeastward winds punctuated by occasional tropical cyclones (TCs); and the cool season (mid-September through April), with a nearly continuous, northeastward progression of energetic extratropical cyclones (ETCs) through the region. Cool season ETCs force the region with strong wind stress and ocean-to-atmosphere heat flux episodes, each with a time-scale of several days. Wind stress fluctuation magnitudes typically exceed mean stress magnitudes in each season by a factor of 3–5. These stresses account for just over 40% of the total current variability in the region, showing the wind to be a major driver of the ocean here. Atmosphere-ocean heat flux is typically into the ocean throughout the warm season (~100 W m-2); it is essentially always out of the ocean during the cool season (~500 W m-2 or more). New results herein include: southward intraseasonal oscillations of the jet stream’s position drove the strongest ETCs (including one “bomb” cyclone); and during the 41 years leading up to and including PEACH, the season-averaged number and strength of atmospheric cyclones passing over the Hatteras coastal ocean have shown little long-term change. Looking ahead, the NSF Pioneer Array is scheduled to be relocated to the northern portion of the Hatteras coastal ocean in 2024, and the NASA SWOT satellite has begun its ocean topography mission, which has a ground-track cross-over here.

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来源期刊
Dynamics of Atmospheres and Oceans
Dynamics of Atmospheres and Oceans 地学-地球化学与地球物理
CiteScore
3.10
自引率
5.90%
发文量
43
审稿时长
>12 weeks
期刊介绍: Dynamics of Atmospheres and Oceans is an international journal for research related to the dynamical and physical processes governing atmospheres, oceans and climate. Authors are invited to submit articles, short contributions or scholarly reviews in the following areas: •Dynamic meteorology •Physical oceanography •Geophysical fluid dynamics •Climate variability and climate change •Atmosphere-ocean-biosphere-cryosphere interactions •Prediction and predictability •Scale interactions Papers of theoretical, computational, experimental and observational investigations are invited, particularly those that explore the fundamental nature - or bring together the interdisciplinary and multidisciplinary aspects - of dynamical and physical processes at all scales. Papers that explore air-sea interactions and the coupling between atmospheres, oceans, and other components of the climate system are particularly welcome.
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