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On Lagrangian drift in shallow-water waves on moderate shear

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posted on 2024-07-11, 07:11 authored by William Phillips, A. Dai, K. K. Tjan
The Lagrangian drift in an O(ϵ) monochromatic wave field on a shear flow, whose characteristic velocity is O(ϵ) smaller than the phase velocity of the waves, is considered. It is found that although shear has only a minor influence on drift in deep-water waves, its influence becomes increasingly important as the depth decreases, to the point that it plays a significant role in shallow-water waves. Details of the shear flow likewise affect the drift. Because of this, two temporal cases common in coastal waters are studied, viz. stress-induced shear, as would arise were the boundary layer wind-driven, and a current-driven shear, as would arise from coastal currents. In the former, the magnitude of the drift (maximum minus minimum) in shallow-water waves is increased significantly above its counterpart, viz. the Stokes drift, in like waves in otherwise quiescent surroundings. In the latter, on the other hand, the magnitude decreases. However, while the drift at the free surface is always oriented in the direction of wave propagation in stress-driven shear, this is not always the case in current-driven shear, especially in long waves as the boundary layer grows to fill the layer. This latter finding is of particular interest vis-à-vis Langmuir circulations, which arise through an instability that requires differential drift and shear of the same sign. This means that while Langmuir circulations form near the surface and grow downwards (top down), perhaps to fill the layer, in stress-driven shear, their counterparts in current-driven flows grow from the sea floor upwards (bottom up) but can never fill the layer.

Funding

Oceanic Conditions within Extreme Tropical Cyclones

Australian Research Council

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Wave-Induced Upper-Ocean Mixing

Australian Research Council

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PDF (Published version)

ISSN

0022-1120

Journal title

Journal of Fluid Mechanics

Volume

660

Issue

pt 3

Pagination

18 pp

Publisher

Cambridge University Press

Copyright statement

Copyright © Cambridge University Press 2010. The published version is reproduced in accordance with the copyright policy of the publisher.

Language

eng

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