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Role of sea ice in global biogeochemical cycles: emerging views and challenges

Authors :
Vancoppenolle, Martin
Meiners, Klaus M.
Michel, Christine
Bopp, Laurent
Brabant, Frédéric
Carnat, Gauthier
Delille, Bruno
Lannuzel, Delphine
Madec, Gurvan
Moreau, Sébastien
Tison, Jean-Louis
van der Merwe, Pier
Vancoppenolle, Martin
Meiners, Klaus M.
Michel, Christine
Bopp, Laurent
Brabant, Frédéric
Carnat, Gauthier
Delille, Bruno
Lannuzel, Delphine
Madec, Gurvan
Moreau, Sébastien
Tison, Jean-Louis
van der Merwe, Pier
Publication Year :
2013

Abstract

Observations from the last decade suggest an important role of sea ice in the global biogeochemical cycles, promoted by (i) active biological and chemical processes within the sea ice; (ii) fluid and gas exchanges at the sea ice interface through an often permeable sea ice cover; and (iii) tight physical, biological and chemical interactions between the sea ice, the ocean and the atmosphere. Photosynthetic micro-organisms in sea ice thrive in liquid brine inclusions encased in a pure ice matrix, where they find suitable light and nutrient levels. They extend the production season, provide a winter and early spring food source, and contribute to organic carbon export to depth. Under-ice and ice edge phytoplankton blooms occur when ice retreats, favoured by increasing light, stratification, and by the release of material into the water column. In particular, the release of iron – highly concentrated in sea ice – could have large effects in the iron-limited Southern Ocean. The export of inorganic carbon transport by brine sinking below the mixed layer, calcium carbonate precipitation in sea ice, as well as active ice-atmosphere carbon dioxide (CO2) fluxes, could play a central role in the marine carbon cycle. Sea ice processes could also significantly contribute to the sulphur cycle through the large production by ice algae of dimethylsulfoniopropionate (DMSP), the precursor of sulphate aerosols, which as cloud condensation nuclei have a potential cooling effect on the planet. Finally, the sea ice zone supports significant ocean–atmosphere methane (CH4) fluxes, while saline ice surfaces activate springtime atmospheric bromine chemistry, setting ground for tropospheric ozone depletion events observed near both poles. All these mechanisms are generally known, but neither precisely understood nor quantified at large scales. As polar regions are rapidly changing, understanding the large-scale polar marine biogeochemical processes and their future evolution is of high prior

Details

Database :
OAIster
Publication Type :
Electronic Resource
Accession number :
edsoai.ocn921268584
Document Type :
Electronic Resource