A model study of differences of snow thinning on Arctic and Antarctic first-year sea ice during spring and summer

The one-dimensional snow model SNTHERM is validated using field measurements of snow and superimposed ice thickness and surface energy fluxes. These were performed during the spring-to-summer transition in Svalbard and in the Weddell Sea, Antarctica. Both the seasonal snow-thickness decrease and the...

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Bibliographic Details
Published in:Annals of Glaciology
Main Authors: Nicolaus, Marcel, Haas, Christian, Bareiss, Jörg, Willmes, Sascha
Format: Article in Journal/Newspaper
Language:English
Published: International Glaciological Society 2006
Subjects:
Antarctic
Arctic
Southern Ocean
Svalbard
The Antarctic
Weddell
Weddell Sea
Annals of Glaciology
Antarc*
Antarctica
Sea ice
Online Access:https://oceanrep.geomar.de/id/eprint/28502/
https://oceanrep.geomar.de/id/eprint/28502/1/Nicolaus_et_al_2006_Annals-of-Glaciaology.pdf
https://doi.org/10.3189/172756406781811312
Description
Summary:The one-dimensional snow model SNTHERM is validated using field measurements of snow and superimposed ice thickness and surface energy fluxes. These were performed during the spring-to-summer transition in Svalbard and in the Weddell Sea, Antarctica. Both the seasonal snow-thickness decrease and the formation of superimposed ice are well reproduced by the model. During the three observation periods, observed and modeled snow thickness differ only by 13.1–27.1mm on average. In regional studies, the model is forced with atmospheric re-analysis data (European Centre for Medium-Range Weather Forecasts) and applied to several meridional transects across the Arctic and Southern Ocean. These show fundamental regional differences in the onset, duration and magnitude of snow thinning in summer. In the central Arctic, snowmelt onset occurs within a narrow time range of +-11 days and without significant regional differences. In contrast, the snow cover on Antarctic sea ice begins to melt about 25days earlier and the length of the Antarctic snow-thinning season increases with increasing latitude. The importance of melting and evaporation for the modeled snow-thickness decrease is very different in the two hemispheres. The ratio of evaporated snow mass to melted snow mass per unit area is derived from the model, and amounts to approximately 4.2 in the Antarctic and only 0.75 in the Arctic. This agrees with observations and model results of the surface energy balance, and illustrates the dominance of surface cooling by upward turbulent fluxes in the Antarctic.

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