Direct Measurements of Mean Reynolds Stress and Ripple Roughness in the Presence of Energetic Forcing by Surface Waves: REYNOLDS STRESS OVER WAVE-FORMED RIPPLES

Q1 Earth and Planetary Sciences

Journal of Geophysical Research Pub Date : 2018-04-01 DOI:10.1002/2017jc013252

M. E. Scully, J. Trowbridge, C. Sherwood, Katie R. Jones, P. Traykovski

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引用次数: 12

Abstract

Direct covariance observations of the mean flow Reynolds stress and sonar images of the seafloor collected on a wave-exposed inner continental shelf demonstrate that the drag exerted by the seabed on the overlying flow is consistent with boundary layer models for wave-current interaction, provided that the orientation and anisotropy of the bed roughness are appropriately quantified. Large spatial and temporal variations in drag result from nonequilibrium ripple dynamics, ripple anisotropy, and the orientation of the ripples relative to the current. At a location in coarse sand characterized by large two-dimensional orbital ripples, the observed drag shows a strong dependence on the relative orientation of the mean current to the ripple crests. At a contrasting location in fine sand, where more isotropic sub-orbital ripples are observed, the sensitivity of the current to the orientation of the ripples is reduced. Further, at the coarse site under conditions when the currents are parallel to the ripple crests and the wave orbital diameter is smaller than the wavelength of the relic orbital ripples, the flow becomes hydraulically smooth. This transition is not observed at the fine site, where the observed wave orbital diameter is always greater than the wavelength of the observed sub-orbital ripples. Paradoxically, the dominant along-shelf flows often experience lower drag at the coarse site than at the fine site, despite the larger ripples, highlighting the complex dynamics controlling drag in wave-exposed environments with heterogeneous roughness.

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在表面波的高能强迫下，平均雷诺应力和波纹粗糙度的直接测量:在波浪形成的波纹上的雷诺应力

对平均流雷诺应力的直接协方差观测和在波浪暴露的内大陆架上收集的海底声纳图像表明，只要对海床粗糙度的方向和各向异性进行适当量化，海床对上覆水流施加的阻力与波流相互作用的边界层模型一致。阻力的巨大空间和时间变化源于非平衡波纹动力学、波纹各向异性以及波纹相对于电流的方向。在粗砂中以大的二维轨道波纹为特征的位置，观测到的阻力强烈依赖于平均电流与波纹峰值的相对方向。在细沙中的对比位置，观察到更多各向同性的亚轨道波纹，电流对波纹方向的敏感性降低。此外，在粗糙的位置，当电流平行于波纹波峰并且波轨道直径小于遗迹轨道波纹的波长时，流动变得水力平滑。在精细位置没有观察到这种跃迁，在精细位置，观察到的波轨道直径总是大于观察到的亚轨道波纹的波长。矛盾的是，尽管波纹较大，但主要的沿陆架流动在粗糙位置的阻力通常比在精细位置的阻力低，这突出了在具有不均匀粗糙度的波浪暴露环境中控制阻力的复杂动力学。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Geophysical Research 地学-地球科学综合

CiteScore

5.80

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： Journal of Geophysical Research (JGR) publishes original scientific research on the physical, chemical, and biological processes that contribute to the understanding of the Earth, Sun, and solar system and all of their environments and components. JGR is currently organized into seven disciplinary sections (Atmospheres, Biogeosciences, Earth Surface, Oceans, Planets, Solid Earth, Space Physics). Sections may be added or combined in response to changes in the science.