黑潮延伸区海洋中尺度涡旋调制的次中尺度垂直热输送的季节性

IF 3.3 2区 地球科学 Q1 OCEANOGRAPHY
Qingyue Wang, Changming Dong, Jihai Dong
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引用次数: 0

摘要

高能中尺度漩涡往往伴随着强烈的次中尺度变率,次中尺度变率在连接海洋中尺度运动和湍流运动方面起着重要作用,并导致强烈的垂直运动。利用高分辨率(1/48°)海洋数值模式 LLC4320 的产物,研究了黑潮延伸区(KE)多个中尺度涡内亚中尺度过程诱发的垂直热输送的季节变化。在不同季节,次中尺度垂直热输送呈现出一致的上升模式,在冬季观测到的垂直热输送幅度明显更高。在冬季,亚中尺度垂直热通量(SVHF)的最大值约占总垂直热通量(VHF)的 60%。这相当于单个漩涡区域的平均海面净热通量。在夏季和秋季,亚中尺度垂直热通量的最大绝对值约占总垂直热通量的 30%。能量分析表明,与垂直浮力通量相关的气压不稳定性对漩涡区域内亚目尺度过程的产生有着至关重要的影响。次中尺度运动受上混合层内的混合层不稳定性、应变诱导锋生成、湍流热风和湍流热风诱导锋生成的影响,而在很大程度上与海洋内部的应变诱导锋生成有关。此外,向上的低频副介尺度垂直热传输是由涡外围的副介尺度次级环流产生的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Seasonality of Submesoscale Vertical Heat Transport Modulated by Oceanic Mesoscale Eddies in the Kuroshio Extension

Energetic mesoscale eddies are often accompanied by strong submesoscale variability, which plays a significant role in connecting mesoscale and turbulent motions in the ocean and leads to strong vertical motions. The product of a high-resolution (1/48°) oceanic numerical model, the LLC4320, is employed to investigate the seasonal variations of vertical heat transport induced by submesoscale processes within multiple mesoscale eddies in the Kuroshio Extension (KE) region. In different seasons, the submesoscale vertical heat transport exhibits a consistent upward pattern, with notably higher magnitudes observed during winter. In winter, the maxima value of submesoscale vertical heat flux (SVHF) can account for approximately 60% of the total vertical heat flux (VHF). This is equivalent to the average net sea surface heat flux in a single eddy region. In summer and autumn, the maxima absolute value of submesoscale vertical heat flux can account for approximately 30% of the total VHF. Energy analysis reveals that baroclinic instability associated with vertical buoyancy flux has a crucial effect on generating submesoscale processes within the eddy region. The submesoscale motions are influenced by the mixed layer instability, strain-induced frontogenesis, turbulent thermal wind and turbulent thermal wind-induced frontogenesis within the upper mixed layer, while they are largely associated with the strain-induced frontogenesis in the ocean interior. Furthermore, the upward low-frequency submesoscale vertical heat transport is generated by submesoscale secondary circulation at eddy peripheries.

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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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