Atmospheric drivers of a winter-to-spring Lagrangian sea-ice drift in the Eastern Antarctic marginal ice zone

Sea-ice drift in the Antarctic marginal ice zone (MIZ) is discussed using data from a 4-month-long drift of a buoy deployed on a pancake ice floe during the winter sea-ice expansion. We demonstrate increased meandering and drift speeds, and changes in the dynamical regimes of the absolute dispersion...

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Bibliographic Details
Published in:Journal of Glaciology
Main Authors: Ashleigh Womack, Marcello Vichi, Alberto Alberello, Alessandro Toffoli
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press 2022
Subjects:
Antarctic glaciology
atmosphere/ice/ocean interactions
sea ice
sea-ice dynamics
Environmental sciences
GE1-350
Meteorology. Climatology
QC851-999
Antarctic
The Antarctic
Austral
Indian
Pancake
Antarc*
Journal of Glaciology
Sea ice
Online Access:https://doi.org/10.1017/jog.2022.14
https://doaj.org/article/45fc3a9c53ca48a4ba8ff59012a12403
Description
Summary:Sea-ice drift in the Antarctic marginal ice zone (MIZ) is discussed using data from a 4-month-long drift of a buoy deployed on a pancake ice floe during the winter sea-ice expansion. We demonstrate increased meandering and drift speeds, and changes in the dynamical regimes of the absolute dispersion during cyclone activity, together with high correlations between drift velocities and wind from atmospheric reanalyses. This indicates a dominant physical control of wind forcing on ice drift and the persistence of free-drift conditions. These conditions occurred despite the buoy remaining largely in >80% ice concentrations and at distances >200 km from the estimated ice edge. The drift is additionally characterised by a strong inertial signature at 13.47 h, which appears initiated by passing cyclones. A wavelet analysis of the buoy's velocity confirms that the momentum transfer from winds at the multi-day frequencies is due to atmospheric forcing, while the initiation of inertial oscillations of sea ice has been identified as the secondary effect. Propagating storm-generated waves may initiate inertial oscillations by increasing the mobility of floes and enhance the drag of the inertial current. This analysis indicates that the Antarctic MIZ in the Indian Ocean sector remains much wider and mobile, during austral winter-to-spring, than defined by sea-ice concentration.

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