4.7 Article

Sea Ice Properties in High-Resolution Sea Ice Models

Journal

JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS
Volume 126, Issue 1, Pages -

Publisher

AMER GEOPHYSICAL UNION
DOI: 10.1029/2020JC016686

Keywords

Arctic; high‐ resolution modeling; sea ice; sea ice rheology; sea ice strength parameter

Categories

Funding

  1. U.S. Department of Homeland Security (DHS) [2014-ST-061-ML-0002]
  2. NASA Cryosphere Program [NNX15AG68G, NNX17AD27G]
  3. NOAA Climate Program Office [NA15OAR4310170]
  4. ONR [N00014-17-1-3162]
  5. NSF Office of Polar Programs [PLR-1603259]
  6. DHS

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Increasing model resolution from 6 to 2 km does not significantly improve model performance in capturing sea ice properties, and it may be unnecessary to constantly adjust model parameters with increasingly high resolutions. While the three model versions yield similar mean state of sea ice, they differ in representing anisotropic properties of sea ice.
An Arctic sea ice-ocean model is run with three uniform horizontal resolutions (6, 4, and 2 km) and identical sea ice and ocean model parameterizations, including an isotropic viscous-plastic sea ice rheology, a mechanical ice strength parameterization, and an ice ridging parameterization. Driven by the same atmospheric forcing, the three model versions all produce similar spatial patterns and temporal variations of ice thickness and motion fields, resulting in almost identical magnitude and seasonal evolution of total ice volume and mean ice concentration, ice speed, and fractions of ice of various thickness categories over the Arctic Ocean. Increasing model resolution from 6 to 2 km does not significantly improve model performance when compared to NASA IceBridge ice thickness observations. This suggests that the large-scale sea ice properties of the model are insensitive to varying high resolutions within the multifloe scale (2-10 km), and it may be unnecessary to adjust model parameters constantly with increasingly high resolutions. This is also true with models within the aggregate scale (10-75 km), indicating that model parameters used at coarse resolution may be used at high or multiscale resolution. However, even though the three versions all yield similar mean state of sea ice, they differ in representing anisotropic properties of sea ice. While they produce a basic pattern of major sea ice leads similar to satellite observations, their leads are distributed differently in space and time. Without changing model parameters and sea ice spatiotemporal variability, the 2-km resolution model tends to capture more leads than the other two models.

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