同质条件下地形和旋转对塑造爱尔兰科里布湖流域尺度环流的影响

Q4 Earth and Planetary Sciences Irish Journal of Earth Sciences Pub Date : 2023-12-01 DOI:10.1353/ijes.0.a916338
Heather Cannaby, Martin White
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引用次数: 0

摘要

地球自转对同质盆地环流模式的影响已利用数值模型进行了深入研究。这篇论文满足了对辅助观测研究的需求。为了证明自转是如何改变爱尔兰克里布湖的环流模式和水平速度剖面的,我们对安装在湖底的声学多普勒海流(ADCP)速度剖面以及漂流器轨迹和数值解进行了分析。科里布湖的风动环流形成了一个地形回旋系统,由盆地复杂的水深形成。尽管该系统受制于浅水深度(平均深度 = 8.4 米)和较小的水平尺寸(约 10 千米),但其表面和海底摩擦边界层仍被证明与经典的埃克曼理论密切相关。观测到的速度剖面可以通过将水流的两个驱动力(气压梯度力和表面风应力)及其对立力(内摩擦力和科里奥利加速度)相加得出。旋转给气流带来了很大的横风成分,因此被称为准地转气流。气压梯度力是根据经验量化的,它是风应力的函数,与水面设置和水面剪切速度有关。根据 ADCP 数据得出的垂直涡流粘度曲线随着深度的增加呈近似线性增加,在海底边界层的上界面处最大。
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The Impact of Topography and Rotation in Shaping the Basin-Scale Circulation in Lough Corrib, Ireland, Under Homogenous Conditions
The impact of the Earth’s rotation on circulation patterns in homogenous basins has been well studied using numerical models. This contribution addresses the need for supporting observational studies. Bottom mounted acoustic doppler current (ADCP) velocity profiles are analysed alongside drifter tracks and numerical solutions in order to demonstrate how rotation modifies circulation patterns and horizontal velocity profiles in Lough Corrib, Ireland. The wind driven circulation in Lough Corrib forms a system of topographic gyres, shaped by the complex bathymetry of the basin. Surface and benthic frictional boundary layers are demonstrated to be closely described by classical Ekman theory, despite the system being constrained by shallow water depths (mean depth = 8.4m) and small horizontal dimensions (~10km). Observed velocity profiles can be derived theoretically by summing the two driving forces of the flow (the barotropic pressure gradient force and the surface wind stress force) and their opposing forces (internal friction and Coriolis acceleration). Rotation introduces a significant cross-wind component to the flow, which is thus described as being quasi-geostrophic. The barotropic pressure gradient force is empirically quantified as a function of wind stress by relating surface set-up to the surface water shear velocity. The vertical eddy viscosity profile, derived from ADCP data, increases approximately linearly with increasing depth and is largest at the upper interface of the benthic boundary layer.
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来源期刊
Irish Journal of Earth Sciences
Irish Journal of Earth Sciences Earth and Planetary Sciences-Earth and Planetary Sciences (all)
CiteScore
0.90
自引率
0.00%
发文量
2
期刊最新文献
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