Linking sea ice deformation to ice thickness redistribution using high-resolution satellite and airborne observations
Permanent lenke
https://hdl.handle.net/10037/24214Dato
2021-05-04Type
Journal articleTidsskriftartikkel
Peer reviewed
Sammendrag
An unusual, large, latent-heat polynya opened and
then closed by freezing and convergence north of Greenland’s coast in late winter 2018. The closing presented a natural but well-constrained full-scale ice deformation experiment. We observed the closing of and deformation within
the polynya with satellite synthetic-aperture radar (SAR) imagery and measured the accumulated effects of dynamic and
thermodynamic ice growth with an airborne electromagnetic
(AEM) ice thickness survey 1 month after the closing began.
During that time, strong ice convergence decreased the area
of the refrozen polynya by a factor of 2.5. The AEM survey
showed mean and modal thicknesses of the 1-month-old ice
of 1.96 ± 1.5 m and 1.1 m, respectively. We show that this
is in close agreement with modeled thermodynamic growth
and with the dynamic thickening expected from the polynya
area decrease during that time. We found significant differences in the shapes of ice thickness distributions (ITDs) in
different regions of the refrozen polynya. These closely corresponded to different deformation histories of the surveyed
ice that we reconstructed from Lagrangian ice drift trajectories in reverse chronological order. We constructed the ice
drift trajectories from regularly gridded, high-resolution drift
fields calculated from SAR imagery and extracted deformation derived from the drift fields along the trajectories. Results show a linear proportionality between convergence and
thickness change that agrees well with the ice thickness redistribution theory. We found a proportionality between the
e folding of the ITDs’ tails and the total deformation experienced by the ice. Lastly, we developed a simple, volumeconserving model to derive dynamic ice thickness change
from the combination of Lagrangian trajectories and highresolution SAR drift and deformation fields. The model has
a spatial resolution of 1.4 km and reconstructs thickness profiles in reasonable agreement with the AEM observations.
The modeled ITD resembles the main characteristics of the
observed ITD, including mode, e folding, and full width at
half maximum. Thus, we demonstrate that high-resolution
SAR deformation observations are capable of producing realistic ice thickness distributions.
Forlag
Copernicus PublicationsSitering
Von Albedyll, Haas, Dierking. Linking sea ice deformation to ice thickness redistribution using high-resolution satellite and airborne observations. The Cryosphere. 2021;15(5):2167-2186Metadata
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