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Read Full Article (file size: 1065219 bytes) Cited by
JOURNAL OF GEOPHYSICAL RESEARCH,
VOL. 110,
C09021,
doi:10.1029/2004JC002834,
2005
Energy and momentum dissipation through wave breaking
Shuwen Zhang
Key Laboratory of Marine Science and Numerical Modeling, First Institute of Oceanography, State Oceanic Administration, Qingdao,
China
Yeli Yuan
Key Laboratory of Marine Science and Numerical Modeling, First Institute of Oceanography, State Oceanic Administration, Qingdao,
China
Abstract
Wave breaking plays an important role in air-sea interaction. Laboratory and field measurements suggest that the wave field
dissipation can be significantly enhanced by wave breaking and acts as a source of energy for generating current and entraining
air against the effect of buoyancy forces. In the present study, a breaking wave model is formulated by taking the acceleration
threshold value of −g/2 as breaking criterion, and the statistics of breaking waves, such as breaking wave coverage per unit time, and the volume
of breaking water per unit area of wave surface per unit time are estimated. Statistical models are also developed to assess
energy and momentum dissipation through wave breaking. It is found that the energy and momentum dissipation rates decay as
k
−3 and k
−2.5, respectively. The energy loss is mainly due to wave components at frequencies higher than the spectral peak frequency. Though
energy loss due to wave components at frequencies lower than the spectral peak frequency is found, these wave components do
not significantly lose energy after the breaking. The energy loss, when expressed as phase speed c
b
of breaking waves, is mainly in the range 0.20 c
p
< c
b
< 0.90 c
p
, where c
p
is the dominant wave phase speed, and the energy dissipation rate falls off rapidly toward shorter scales. This offers no
support for the hypothesis of a “Kolmogorov cascade” in wind-generated waves analogous to that in turbulence, with energy
input from the wind at large scales and dissipation from the waves at the smallest scales. It is also demonstrated that, compared
with empirical formula results, our model of energy (or momentum) dissipation rate lies between those models that estimate
by empirical formula the rate of energy (or momentum) loss from a breaker with proportional coefficients 0.0085 and 0.0007.
In addition, the peak frequency of our model energy (or momentum) dissipation rate downshifts to the lower-frequency band
as wind speed increases, whereas the peak of the empirical formula remains at the same frequency.
Received 2
December
2004;
accepted 27
May
2005;
published 28
September
2005.
Keywords: air-sea interaction;
breaking waves;
energy and momentum dissipation.
Index Terms: 0312 Atmospheric Composition and Structure: Air/sea constituent fluxes (3339, 4504); 3339 Atmospheric Processes: Ocean/atmosphere interactions (0312, 4504); 1222 Geodesy and Gravity: Ocean monitoring with geodetic techniques (1225, 1641, 3010, 4532, 4556, 4560, 6959); 4506 Oceanography: Physical: Capillary waves.
Read Full Article (file size: 1065219 bytes) Cited by
Citation: Zhang, S., and Y. Yuan
(2005),
Energy and momentum dissipation through wave breaking,
J. Geophys. Res.,
110,
C09021,
doi:10.1029/2004JC002834.
Copyright 2005 by the American Geophysical Union.
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