Attenuation and directional spreading of ocean wave spectra in the marginal ice zone

Montiel, Fabien; Squire, Vernon A.; Bennetts, Luke G.

doi:10.1017/jfm.2016.21

Cited by 100 publications

(121 citation statements)

References 61 publications

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“…New models have been developed as part of this program (e.g., Montiel et al, ), and thus there is an expanding set of schemes to implement and test in WAVEWATCH III. These are noted by “ICn” for dissipation terms and “ISn” for scattering terms.…”

Section: Methodsmentioning

confidence: 99%

Overview of the Arctic Sea State and Boundary Layer Physics Program

Ackley²,

et al. 2018

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A large collaborative program has studied the coupled air‐ice‐ocean‐wave processes occurring in the Arctic during the autumn ice advance. The program included a field campaign in the western Arctic during the autumn of 2015, with in situ data collection and both aerial and satellite remote sensing. Many of the analyses have focused on using and improving forecast models. Summarizing and synthesizing the results from a series of separate papers, the overall view is of an Arctic shifting to a more seasonal system. The dramatic increase in open water extent and duration in the autumn means that large surface waves and significant surface heat fluxes are now common. When refreezing finally does occur, it is a highly variable process in space and time. Wind and wave events drive episodic advances and retreats of the ice edge, with associated variations in sea ice formation types (e.g., pancakes, nilas). This variability becomes imprinted on the winter ice cover, which in turn affects the melt season the following year.

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Section: Methodsmentioning

confidence: 99%

Overview of the Arctic Sea State and Boundary Layer Physics Program

Ackley²,

et al. 2018

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“…We also seek to quantify how the directionality of the wavefield changes as waves propagate in the pancake ice cover, as this may inform what the dominant processes governing wave‐ice interactions are in this particular experiment. There is observational (see ; Sutherland & Gascard, ; Wadhams et al, ) and theoretical (see Montiel et al, ; Squire & Montiel, ) evidence suggesting that short waves traveling through the MIZ tend to experience a broadening of the range of wave directions as a result of wave scattering by the constituent ice floes, while long waves have been hypothesized to experience a decrease in their directional range, likely caused by dissipative effects gradually filtering out spectral components. Since dissipative effects dominate over scattering in pancake ice, we expect this latter scenario to govern our wave directionality data.…”

Section: Datamentioning

confidence: 99%

Attenuation and Directional Spreading of Ocean Waves During a Storm Event in the Autumn Beaufort Sea Marginal Ice Zone

et al. 2018

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This paper investigates the attenuation and directional spreading of large amplitude waves traveling through pancake ice. Directional spectral density is analyzed from in situ wave buoy data collected during a 3‐day storm event in October 2015 in the Beaufort Sea. Two proxy metrics for wave amplitude obtained from energy density spectra, namely, spectral amplitude and significant wave height, are used to track the waves as they propagate along transects through the array of buoys in the predominantly pancake ice field. Two types of wave buoys are used in the analysis and compared, exhibiting significant differences in the wave energy density and directionality estimates. Although exponential decay is observed predominantly, one of the two buoy types indicates a potential positive correlation between wave energy density and the occurrence of linear wave decay, as opposed to exponential decay, in accord with recent observations in the Antarctic marginal ice zone. Factors affecting the validity of this observation are discussed. An empirical power law with exponent 2.2 is also found to hold between the exponential attenuation coefficient and wave frequency. The directional content of the wave spectrum appears to decrease consistently along the wave transects, confirming that wave energy is being dissipated by the pancake ice as opposed to being scattered by ice cakes.

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“…Two model paradigms exist to understand wave attenuation. The first is wave scattering (e.g., Bennetts & Squire, ; Kohout & Meylan, ; Montiel et al, ; Peter & Meylan, ), which conserves energy and in which attenuation results from an accumulation of scattering events produced by individual floes, where the floes are conventionally modeled as thin floating elastic plates (e.g., Bennetts & Williams, ; Meylan & Squire, ). Scattering models have been shown to agree reasonably well with experimental measurements (Bennetts & Squire, ; Bennetts & Williams, ; Bennetts et al, ; Kohout & Meylan, ), but only when wavelengths are comparable to floe lengths.…”

Section: Introductionmentioning

confidence: 99%

Dispersion Relations, Power Laws, and Energy Loss for Waves in the Marginal Ice Zone

et al. 2018

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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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Attenuation and directional spreading of ocean wave spectra in the marginal ice zone

Cited by 100 publications

References 61 publications

Overview of the Arctic Sea State and Boundary Layer Physics Program

Overview of the Arctic Sea State and Boundary Layer Physics Program

Attenuation and Directional Spreading of Ocean Waves During a Storm Event in the Autumn Beaufort Sea Marginal Ice Zone

Dispersion Relations, Power Laws, and Energy Loss for Waves in the Marginal Ice Zone

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