On the Dissipation Rate of Ocean Waves due to White Capping

We calculate the rate of ocean wave energy dissipation due to white capping by numerical simulation of deterministic phase resolving model for dynamics of ocean surface. Two independent numerical experiments are performed. First, we solve the 3D Hamiltonian equation that includes three- and four-wav...

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Bibliographic Details
Published in:JETP letters 2019-03, Vol.109 (5), p.309-315
Main Authors: Korotkevich, A. O., Prokofiev, A. O., Zakharov, V. E.
Format: Article
Language:English
Subjects:
Atomic
Biological and Medical Physics
Biophysics
Capping
Computer simulation
Conformal mapping
Energy dissipation
Euler-Lagrange equation
Free surfaces
Hydro- and Gas Dynamics
Ideal fluids
Mathematical models
Molecular
Ocean surface
Ocean waves
Optical and Plasma Physics
Particle and Nuclear Physics
Physics
Physics and Astronomy
Plasma
Potential flow
Quantum Information Technology
Slopes
Solid State Physics
Spintronics
Wave interaction
Wave power
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Summary:We calculate the rate of ocean wave energy dissipation due to white capping by numerical simulation of deterministic phase resolving model for dynamics of ocean surface. Two independent numerical experiments are performed. First, we solve the 3D Hamiltonian equation that includes three- and four-wave interactions. This model is valid only for moderate values of the surface steepness, μ < 0.09. Then we solve the exact Euler equation for non-stationary potential flow of an ideal fluid with a free surface in 2D geometry. We use the conformal mapping of domain filled with fluid onto the lower half-plane. This model is applicable for arbitrary high levels of the steepness. The results of both experiments are close. The white capping is the threshold process that takes place if the average steepness μ > μ cr ≃ 0.055. The rate of energy dissipation grows dramatically with increasing steepness. Comparison of our results with dissipation functions used in the operational models of wave forecasting shows that these models overestimate the rate of wave dissipation by order of magnitude for typical values of the steepness.
ISSN:0021-3640
1090-6487
DOI:10.1134/S0021364019050035