Dispersion relations, power laws, and energy loss for waves in the marginal ice zone

Analysis of field measurements of ocean surface wave activity in the marginal ice zone, from campaigns in the Arctic and Antarctic and over a range of different ice conditions, shows the wave attenuation rate with respect to distance has a power law dependence on the frequency with order between two...

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Bibliographic Details
Main Authors: Meylan, M. H., Bennetts, L. G., Mosig, J. E. M., Rogers, W. E., Doble, M. J., Peter, M. A.
Other Authors: The University of Newcastle. Faculty of Science, School of Mathematical and Physical Sciences
Format: Article in Journal/Newspaper
Language:English
Published: Wiley-Blackwell 2018
Subjects:
marginal ice zone
wave attenuation
energy loss
power laws
Antarctic
Arctic
Antarc*
Online Access:http://hdl.handle.net/1959.13/1393602
Description
Summary:Analysis of field measurements of ocean surface wave activity in the marginal ice zone, from campaigns in the Arctic and Antarctic and over a range of different ice conditions, shows the wave attenuation rate with respect to distance has a power law dependence on the frequency with order between two and four. With this backdrop, the attenuation‐frequency power law dependencies given by three dispersion relation models are obtained under the assumptions of weak attenuation, negligible deviation of the wave number from the open water wave number, and thin ice. It is found that two of the models (both implemented in WAVEWATCH III®), predict attenuation rates that are far more sensitive to frequency than indicated by the measurements. An alternative method is proposed to derive dispersion relation models, based on energy loss mechanisms. The method is used to generate example models that predict power law dependencies that are comparable with the field measurements.

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