Drift of pancake ice floes in the winter Antarctic marginal ice zone during polar cyclones
Alberello, A.; Bennetts, L.; Heil, P.; Eayrs, C.; Vichi, M.; MacHutchon, K.; Onorato, M.; Toffoli, A. (2020). Drift of pancake ice floes in the winter Antarctic marginal ice zone during polar cyclones. JGR: Oceans 125(3): e2019JC015418. https://dx.doi.org/10.1029/2019JC015418 In: Journal of Geophysical Research-Oceans. AMER GEOPHYSICAL UNION: Washington. ISSN 2169-9275; e-ISSN 2169-9291, more | |
Keyword | | Author keywords | sea ice; marginal ice zone; drift; pancake ice; Antarctic; buoy |
Authors | | Top | - Alberello, A.
- Bennetts, L.
- Heil, P.
- Eayrs, C.
| - Vichi, M.
- MacHutchon, K.
- Onorato, M.
- Toffoli, A., more
| |
Abstract | 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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