Turbulent heat flux dynamics along the Dotson and Getz ice-shelf fronts (Amundsen Sea, Antarctica)

In coastal polynyas, where sea–ice formation occurs, it is crucial to have accurate estimates of heat fluxes in order to predict future rates of sea–ice formation. The Amundsen Sea Polynya is the fourth largest coastal polynya around Antarctica, yet remains poorly observed becaus...

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Bibliographic Details
Main Authors: Jacob, Blandine, Queste, Bastien Y., Plessis, Marcel D.
Format: Text
Language:English
Published: 2024
Subjects:
Amundsen Sea
Antarc*
Antarctica
Getz Ice Shelf
Ice Shelf
Ice Shelves
Online Access:https://doi.org/10.5194/egusphere-2024-2076
https://egusphere.copernicus.org/preprints/2024/egusphere-2024-2076/
Description
Summary:In coastal polynyas, where sea–ice formation occurs, it is crucial to have accurate estimates of heat fluxes in order to predict future rates of sea–ice formation. The Amundsen Sea Polynya is the fourth largest coastal polynya around Antarctica, yet remains poorly observed because of its remoteness. Consequently, we rely on models and reanalysis that are unvalidated to study the effect of atmospheric forcing on polynya dynamics. We use summer ship-board data from the NBP22/02 cruise to understand the turbulent heat flux dynamics in the Amundsen Sea Polynya and evaluate our ability to represent these dynamics in ERA5. We show that cold and dry air outbreaks from Antarctica enhance air–sea temperature and humidity gradients, triggering episodic heat loss events. The heat loss is larger along the ice shelves, and it is also where the ERA5 turbulent heat flux exhibits the largest biases, underestimating the flux by up to 141 W m -2 due to its coarse resolution and misrepresentation of ice-shelf location. By reconstructing a turbulent heat flux product from ERA5 variables using a nearest neighbour approach to obtain sea surface temperature, we decrease the bias to 107 W m -2 . Using a 1D-model, we show that the mean co-located ERA5 heat loss underestimation of -28 W m -2 led to an overestimation of the summer evolution of sea surface temperature (heat content) by +0.76 °C (+8.2×10 7 J) over 35-days. By obtaining the reconstructed flux, the reduced heat loss bias (12 W m -2 ) reduced the seasonal bias in sea surface temperature (heat content) to -0.17 °C (-3.30×10 7 J) over the 35–days. This study shows that caution should be applied when retrieving ERA5 turbulent flux along the ice shelves, and that a reconstructed flux using ERA5 variables shows better accuracy.

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