Estimating early-winter Antarctic sea ice thickness from deformed ice morphology

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Mei, M. J., Maksym, T., Weissling, B., & Singh, H. Estimating early-winter Antarctic sea ice thickness from deformed ice morphology. Cryosphere,...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: Mei, M. Jeffrey, Maksym, Ted, Weissling, Blake, Singh, Hanumant
Format: Article in Journal/Newspaper
Language:unknown
Published: European Geosciences Union 2019
Subjects:
Antarctic
The Antarctic
Antarc*
Sea ice
Online Access:https://hdl.handle.net/1912/25395
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Summary:© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Mei, M. J., Maksym, T., Weissling, B., & Singh, H. Estimating early-winter Antarctic sea ice thickness from deformed ice morphology. Cryosphere, 13(11), (2019): 2915-2934, doi:10.5194/tc-13-2915-2019. Satellites have documented variability in sea ice areal extent for decades, but there are significant challenges in obtaining analogous measurements for sea ice thickness data in the Antarctic, primarily due to difficulties in estimating snow cover on sea ice. Sea ice thickness (SIT) can be estimated from snow freeboard measurements, such as those from airborne/satellite lidar, by assuming some snow depth distribution or empirically fitting with limited data from drilled transects from various field studies. Current estimates for large-scale Antarctic SIT have errors as high as ∼50 %, and simple statistical models of small-scale mean thickness have similarly high errors. Averaging measurements over hundreds of meters can improve the model fits to existing data, though these results do not necessarily generalize to other floes. At present, we do not have algorithms that accurately estimate SIT at high resolutions. We use a convolutional neural network with laser altimetry profiles of sea ice surfaces at 0.2 m resolution to show that it is possible to estimate SIT at 20 m resolution with better accuracy and generalization than current methods (mean relative errors ∼15 %). Moreover, the neural network does not require specification of snow depth or density, which increases its potential applications to other lidar datasets. The learned features appear to correspond to basic morphological features, and these features appear to be common to other floes with the same climatology. This suggests that there is a relationship between the surface morphology and the ice thickness. The model has a mean relative error of 20 % when applied to a new floe from the region and ...

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