Wave–ice interactions in the neXtSIM sea-ice model

Williams, Timothy; Rampal, Pierre; Bouillon, Sylvain

doi:10.5194/tc-11-2117-2017

Cited by 49 publications

(41 citation statements)

References 54 publications

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“…By calibrating C a and C w properly, free drift with no internal stress or wave effect, as might be caused by Stokes drift (Yiew et al, 2017), slope sliding (Grotmaack & Meylan, 2006), or wave radiation stresses (Masson, 1991), produces very good model results compared with observations, especially under storm conditions. Williams et al (2017) and Boutin et al (2019) recently integrated wave radiation stresses into large-scale numerical models that include wave attenuation and wave-induced ice breakup, based on the wave-ice interaction model of Williams et al (2013aWilliams et al ( , 2013b. They found that large wave radiation stresses, proportional to the wave attenuation rate, remain concentrated at the edge (Williams et al, 2017); wind and ocean stresses dominate ice drift over longer distances.…”

Section: Discussionmentioning

confidence: 99%

“…Williams et al (2017) and Boutin et al (2019) recently integrated wave radiation stresses into large-scale numerical models that include wave attenuation and wave-induced ice breakup, based on the wave-ice interaction model of Williams et al (2013aWilliams et al ( , 2013b. They found that large wave radiation stresses, proportional to the wave attenuation rate, remain concentrated at the edge (Williams et al, 2017); wind and ocean stresses dominate ice drift over longer distances. Moreover, Williams et al (2017) found that wave radiation stresses are appreciable only for wave periods < 10 s; the measurements reported here have dominant periods > 15 s. The small floes observed during our measurements, smaller floes than tested by Williams et al (2017), would induce even weaker radiation stresses.…”

Section: Discussionmentioning

confidence: 99%

“…They found that large wave radiation stresses, proportional to the wave attenuation rate, remain concentrated at the edge (Williams et al, 2017); wind and ocean stresses dominate ice drift over longer distances. Moreover, Williams et al (2017) found that wave radiation stresses are appreciable only for wave periods < 10 s; the measurements reported here have dominant periods > 15 s. The small floes observed during our measurements, smaller floes than tested by Williams et al (2017), would induce even weaker radiation stresses. Although wave-induced drift is negligible, it is expected that the significant waves measured will have induced turbulence in the water sublayers (Alberello, Onorato, Frascoli, et al, 2019;Smith & Thomson, 2019;Zippel & Thomson, 2016), enhancing mixing and heat fluxes under sea ice (Ackley et al, 2015;Smith et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

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Drift of Pancake Ice Floes in the Winter Antarctic Marginal Ice Zone During Polar Cyclones

et al. 2020

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High temporal resolution in situ measurements of pancake ice drift are presented, from a pair of buoys deployed on floes in the Antarctic marginal ice zone during the winter sea ice expansion, over 9 days in which the region was impacted by four polar cyclones. Concomitant measurements of wave‐in‐ice activity from the buoys are used to infer that the ice remained unconsolidated, and pancake ice conditions were maintained over at least the first 7 days. Analysis of the data shows (i) the fastest reported ice drift speeds in the Southern Ocean; (ii) high correlation of drift velocities with the surface wind velocities, indicating absence of internal ice stresses >100 km from the ice edge where remotely sensed ice concentration is 100%; and (iii) presence of a strong inertial signature with a 13 hr period. A Lagrangian free drift model is developed, including a term for geostrophic currents that reproduce the 13 hr period signature in the ice motion. The calibrated model provides accurate predictions of the ice drift for up to 2 days, and the calibrated parameters provide estimates of wind and ocean drag for pancake floes under storm conditions.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Drift of Pancake Ice Floes in the Winter Antarctic Marginal Ice Zone During Polar Cyclones

et al. 2020

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“…The MIZ is a complex and heterogeneous environment, which comprises of ice floes of arbitrary shape and a variety of ice types from newly formed ice to fragmented multi-year ice. While surface waves are expected to be a dominant process controlling the total extent of the MIZ as well as the size distribution of ice floes, there still exist large uncertainties about the exact mechanisms for wave attenuation in sea ice (Williams et al, 2013(Williams et al, , 2017Kohout et al, 2014;Meylan et al, 2014). In addition to affecting the floe size distribution, the attenuation of surface gravity waves is also important in controlling the extent of the MIZ via the wave radiation stress (Liu et al, 1993;Williams et al, 2017;Sutherland & Dumont, 2018).…”

Section: Introductionmentioning

confidence: 99%

A two layer model for wave dissipation in sea ice

Sutherland

Rabault

Christensen

et al. 2019

Applied Ocean Research

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Sea ice is highly complex due to the inhomogeneity of the physical properties (e.g. temperature and salinity) as well as the permeability and mixture of water and a matrix of sea ice and/or sea ice crystals. Such complexity has proven itself to be difficult to parameterize in operational wave models. Instead, we assume that there exists a self-similarity scaling law which captures the first order properties. Using dimensional analysis, an equation for the kinematic viscosity is derived, which is proportional to the wave frequency and the ice thickness squared. In addition, the model allows for a two-layer structure where the oscillating pressure gradient due to wave propagation only exists in a fraction of the total ice thickness. These two assumptions lead to a spatial dissipation rate that is a function of ice thickness and wavenumber. The derived dissipation rate compares favourably with available field and laboratory observations.

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“…Parameterizations of waveice interactions for large-scale continuum models (i.e., those in which ice is treated as a continuous mass rather than as discrete particles) are crucial for further development of those models. However, although appreciable effort has been made in that direction in recent years (Dumont et al, 2011;Doble and Bidlot, 2013;Squire et al, 2013;Williams et al, 2013Williams et al, , 2017; The WAVEWATCH III®Development Group , WW3-DG; Bennetts et al, 2017), our understanding of many aspects of wave-ice interactions is still too limited to allow formulating such parameterizations, especially those suitable for a wide range of conditions. Strong fragmentation of the in the above-mentioned parameterizations by Williams et al (2013), Bennetts et al (2017), and others.…”

Section: Introductionmentioning

confidence: 99%

Wave-induced stress and breaking of sea ice in a coupled hydrodynamic discrete-element wave–ice model

Herman

2017

The Cryosphere

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Abstract. In this paper, a coupled sea ice-wave model is developed and used to analyze wave-induced stress and breaking in sea ice for a range of wave and ice conditions. The sea ice module is a discrete-element bonded-particle model, in which ice is represented as cuboid "grains" floating on the water surface that can be connected to their neighbors by elastic joints. The joints may break if instantaneous stresses acting on them exceed their strength. The wave module is based on an open-source version of the Non-Hydrostatic WAVE model (NHWAVE). The two modules are coupled with proper boundary conditions for pressure and velocity, exchanged at every wave model time step. In the present version, the model operates in two dimensions (one vertical and one horizontal) and is suitable for simulating compact ice in which heave and pitch motion dominates over surge. In a series of simulations with varying sea ice properties and incoming wavelength it is shown that wave-induced stress reaches maximum values at a certain distance from the ice edge. The value of maximum stress depends on both ice properties and characteristics of incoming waves, but, crucially for ice breaking, the location at which the maximum occurs does not change with the incoming wavelength. Consequently, both regular and random (Jonswap spectrum) waves break the ice into floes with almost identical sizes. The width of the zone of broken ice depends on ice strength and wave attenuation rates in the ice.

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Wave–ice interactions in the neXtSIM sea-ice model

Cited by 49 publications

References 54 publications

Drift of Pancake Ice Floes in the Winter Antarctic Marginal Ice Zone During Polar Cyclones

Drift of Pancake Ice Floes in the Winter Antarctic Marginal Ice Zone During Polar Cyclones

A two layer model for wave dissipation in sea ice

Wave-induced stress and breaking of sea ice in a coupled hydrodynamic discrete-element wave–ice model

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