|A model reconstruction of the Antarctic sea ice thickness and volume changes over 1980-2008 using data assimilation|Massonnet, F.; Mathiot, P.; Fichefet, T.; Goosse, H.; König Beatty, C.; Vancoppenolle, M.; Lavergne, T. (2013). A model reconstruction of the Antarctic sea ice thickness and volume changes over 1980-2008 using data assimilation. Ocean Modelling 64: 67-75. dx.doi.org/10.1016/j.ocemod.2013.01.003
In: Ocean Modelling. Elsevier: Oxford. ISSN 1463-5003, more
Antarctic; Sea ice thickness and volume; Data assimilation; EnKF;Trends; Variability; Southern Ocean
|Authors|| || Top |
- Massonnet, F., more
- Mathiot, P.
- Fichefet, T., more
- Goosse, H., more
- König Beatty, C., more
- Vancoppenolle, M.
- Lavergne, T.
Sea ice variability in the Southern Ocean has a complex spatio-temporal structure. In a global warming context, the Antarctic sea ice cover has slightly expanded over the recent decades. This increase in sea ice extent results, however, from the sum of positive and negative regional trends and is influenced by a wide range of modes of climate variability. An additional view on sea ice thickness and volume changes would improve our understanding. Still, no large-scale multi-decadal well-sampled record of Antarctic sea ice thickness exists to date. To address this issue, we assimilate real sea ice concentration data into the ocean–sea ice model NEMO-LIM2 using an ensemble Kalman filter and demonstrate the positive impacts on the global sea ice cover. This paper reports the 1980–2008 evolution (monthly anomalies, trends plus their uncertainty ranges) of sea ice volume and thickness in different sectors of the Southern Ocean. We find that the global Antarctic sea ice volume has risen at a pace of 355±338355±338 km3/decade (5.6±5.35.6±5.3%/decade) during this period, with an increase in the Ross and Weddell Seas (150±124150±124 and 209±362209±362 km3/decade, respectively) and a decrease in the Amundsen–Bellingshausen Seas (-45±54-45±54 km3/decade). Sea ice volume anomalies co-vary well with extent anomalies, and exhibit yearly to decadal fluctuations. The results stress the need to analyze sea ice changes at the regional level first and then at the hemispheric level.