Sea ice CO2 dynamics across seasons: impact of processes at the interfaces

Van der Linden, F.C.; Tison, J.-L.; Champenois, W.; Moreau, S.; Carnat, G.; Kotovitch, M.; Fripiat, F.; Deman, F.; Roukaerts, A.; Dehairs, F.; Wauthy, S.; Lourenço, A.; Vivier, F.; Haskell, T.; Delille, B.

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Sea ice CO₂ dynamics across seasons: impact of processes at the interfaces

Van der Linden, F.C.; Tison, J.-L.; Champenois, W.; Moreau, S.; Carnat, G.; Kotovitch, M.; Fripiat, F.; Deman, F.; Roukaerts, A.; Dehairs, F.; Wauthy, S.; Lourenço, A.; Vivier, F.; Haskell, T.; Delille, B. (2020). Sea ice CO₂ dynamics across seasons: impact of processes at the interfaces. JGR: Oceans 125(6): e2019JC015807. https://hdl.handle.net/10.1029/2019JC015807

In: Journal of Geophysical Research-Oceans. AMER GEOPHYSICAL UNION: Washington. ISSN 2169-9275; e-ISSN 2169-9291, meer

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VLIZ: Non-open access 361613 [ aanvragen ]

Trefwoord

Marien/Kust

Author keywords

Antarctica; air-sea ice fluxes; carbon dioxide; sea ice; trophic status; biofilm

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Van der Linden, F.C. Tison, J.-L. Champenois, W. Moreau, S. Carnat, G.	Kotovitch, M. Fripiat, F. Deman, F. Roukaerts, A. Dehairs, F.	Wauthy, S. Lourenço, A. Vivier, F. Haskell, T. Delille, B.

Abstract

Winter to summer CO₂ dynamics within landfast sea ice in McMurdo Sound (Antarctica) were investigated using bulk ice pCO₂ measurements, air-snow-ice CO₂ fluxes, dissolved inorganic carbon (DIC), total alkalinity (TA), and ikaite saturation state. Our results suggest depth-dependent biotic and abiotic controls that led us to discriminate the ice column in three layers. At the surface, winter pCO₂ supersaturation drove CO₂ release to the atmosphere while spring-summer pCO₂ undersaturation led to CO₂ uptake most of the time. CO₂ fluxes showed a diel pattern superimposed upon this seasonal pattern which was potentially assigned to either ice skin freeze-thaw cycles or diel changes in net community production. In the ice interior, the pCO₂ decrease across the season was driven by physical processes, mainly independent of the autotrophic and heterotrophic phases. Bottom sea ice was characterized by a massive biomass build-up counterintuitively associated with transient heterotrophic activity and nitrate plus nitrite accumulation. This inconsistency is likely related to the formation of a biofilm. This biofilm hosts both autotrophic and heterotrophic activities at the bottom of the ice during spring and may promote calcium carbonate precipitation.

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