Thickness simulation of landfast ice along Mawson Coast, East Antarctica based on a snow/ice high-resolution thermodynamic model

Landfast ice plays an important role in atmosphere-ocean interactions and ecosystems in the near coast area of Antarctica. Understanding the characteristics and variations of landfast ice is crucial to the study of climates and field activities in Antarctic. In this study, a high-resolution thermodynamic snow-ice (HIGHTSI) model was applied to simulate the seasonal changes of landfast ice along the Mawson Coast, East Antarctica, through ERA-Interim reanalysis data. Four ocean heat-flux (Fw) values (10, 15, 20 and 25 W m(-2)) were used in sensitivity experiments. The results showed that it is reasonable to simulate landfast ice using the HIGHTSI model, and the simulation of landfast ice thickness matched best well with field measurements when Fw was 20 W m(-2). Then, 2-D distributions of landfast ice from 2006 to 2018 were modeled by HIGHTSI with 2-D ERA-Interim reanalysis data in a 0.125 degrees x 0.125 degrees cell grid as external forcing. The results showed that fast ice was thicker along the coast and thinner near open water, and usually reaches its maximal thickness in October, varying from 1.2 to 2.0 m through the study area. There was no statistical trend for the thickness during the study period.

Automated summary

Landfast ice plays a crucial role in atmosphere-ocean interactions and ecosystems in the near coast area of Antarctica. This study applied a high-resolution thermodynamic snow-ice (HIGHTSI) model to simulate the seasonal changes of landfast ice along the Mawson Coast, East Antarctica. The results showed that the HIGHTSI model is suitable for simulating landfast ice, with the best match to field measurements achieved when using a specific ocean heat flux value. Furthermore, the study modeled the 2-D distributions of landfast ice from 2006 to 2018 and found that the thickness varies along the coast without a statistical trend.