The theory of fifth-order Stokes waves in a linear shear current

Haiqi Fang; Philip L.F. Liu; Lian Tang; Pengzhi Lin

doi:10.1098/rspa.2023.0565

The theory of fifth-order Stokes waves in a linear shear current

Haiqi Fang, Philip L.F. Liu, Lian Tang, Pengzhi Lin

Department of Hydraulic and Ocean Engineering

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

In this study, a new set of fifth-order Stokes wave solutions, incorporating the effects of a linear shear current, is derived by using the perturbation method originally proposed for pure waves that was recently published. The present solutions are checked against the existing experimental data, the third-order stream function solutions, as well as the numerical results. The comparisons demonstrate that the present solutions are more accurate in describing the velocity distributions during wave propagation, especially in strong following currents and negative vorticity conditions. Subsequently, the present solutions are used to investigate the fluid particle trajectories for different wave-current interaction conditions. The results indicate that the background vorticity can alter the patterns of fluid particle trajectories and the direction of Stokes drifts.

Original language	English
Article number	20230565
Journal	Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume	479
Issue number	2280
DOIs	https://doi.org/10.1098/rspa.2023.0565
Publication status	Published - 2023 Dec 20

All Science Journal Classification (ASJC) codes

General Mathematics
General Engineering
General Physics and Astronomy

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abstract = "In this study, a new set of fifth-order Stokes wave solutions, incorporating the effects of a linear shear current, is derived by using the perturbation method originally proposed for pure waves that was recently published. The present solutions are checked against the existing experimental data, the third-order stream function solutions, as well as the numerical results. The comparisons demonstrate that the present solutions are more accurate in describing the velocity distributions during wave propagation, especially in strong following currents and negative vorticity conditions. Subsequently, the present solutions are used to investigate the fluid particle trajectories for different wave-current interaction conditions. The results indicate that the background vorticity can alter the patterns of fluid particle trajectories and the direction of Stokes drifts.",

author = "Haiqi Fang and Liu, {Philip L.F.} and Lian Tang and Pengzhi Lin",

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T1 - The theory of fifth-order Stokes waves in a linear shear current

AU - Fang, Haiqi

AU - Liu, Philip L.F.

AU - Tang, Lian

AU - Lin, Pengzhi

PY - 2023/12/20

Y1 - 2023/12/20

N2 - In this study, a new set of fifth-order Stokes wave solutions, incorporating the effects of a linear shear current, is derived by using the perturbation method originally proposed for pure waves that was recently published. The present solutions are checked against the existing experimental data, the third-order stream function solutions, as well as the numerical results. The comparisons demonstrate that the present solutions are more accurate in describing the velocity distributions during wave propagation, especially in strong following currents and negative vorticity conditions. Subsequently, the present solutions are used to investigate the fluid particle trajectories for different wave-current interaction conditions. The results indicate that the background vorticity can alter the patterns of fluid particle trajectories and the direction of Stokes drifts.

AB - In this study, a new set of fifth-order Stokes wave solutions, incorporating the effects of a linear shear current, is derived by using the perturbation method originally proposed for pure waves that was recently published. The present solutions are checked against the existing experimental data, the third-order stream function solutions, as well as the numerical results. The comparisons demonstrate that the present solutions are more accurate in describing the velocity distributions during wave propagation, especially in strong following currents and negative vorticity conditions. Subsequently, the present solutions are used to investigate the fluid particle trajectories for different wave-current interaction conditions. The results indicate that the background vorticity can alter the patterns of fluid particle trajectories and the direction of Stokes drifts.

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The theory of fifth-order Stokes waves in a linear shear current

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