Winter observations of CO 2 exchange between sea ice and the atmosphere in a coastal fjord environment

Eddy covariance observations of CO 2 fluxes were conducted during March-April 2012 in a temporally sequential order for 8, 4 and 30 days, respectively, at three locations on fast sea ice and on newly formed polynya ice in a coastal fjord environment in northeast Greenland. CO 2 fluxes at the sites c...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: Sievers, Jakob, Sørensen, Lise Lotte, Papakyriakou, T. N., Sejr, Mikael Kristian, Søgaard, Dorte, Barber, David, Rysgaard, Søren
Format: Article in Journal/Newspaper
Language:English
Published: 2015
Subjects:
Greenland
Sea ice
Online Access:https://pure.au.dk/portal/da/publications/winter-observations-of-co2-exchange-between-sea-ice-and-the-atmosphere-in-a-coastal-fjord-environment(4d47b151-a529-48c4-94b2-7b3f9bd91ec7).html
https://doi.org/10.5194/tc-9-1701-2015
http://www.scopus.com/inward/record.url?scp=84940054554&partnerID=8YFLogxK
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Summary:Eddy covariance observations of CO 2 fluxes were conducted during March-April 2012 in a temporally sequential order for 8, 4 and 30 days, respectively, at three locations on fast sea ice and on newly formed polynya ice in a coastal fjord environment in northeast Greenland. CO 2 fluxes at the sites characterized by fast sea ice (ICEI and DNB) were found to increasingly reflect periods of strong outgassing in accordance with the progression of springtime warming and the occurrence of strong wind events: F CO2 ICE1 = 1.73 ± 5 mmol m -2 day -1 and F CO2 DNB = 8.64 ± 39.64 mmol m -2 day -1 , while CO 2 fluxes at the polynya site (POLYI) were found to generally reflect uptake F CO2 POLY1 = -9.97 ± 19.8 mmol m -2 day -1 . Values given are the mean and standard deviation, and negative/positive values indicate uptake/outgassing, respectively. A diurnal correlation analysis supports a significant connection between site energetics and CO 2 fluxes linked to a number of possible thermally driven processes, which are thought to change the pCO 2 gradient at the snow-ice interface. The relative influence of these processes on atmospheric exchanges likely depends on the thickness of the ice. Specifically, the study indicates a predominant influence of brine volume expansion/contraction, brine dissolution/concentration and calcium carbonate formation/dissolution at sites characterized by a thick sea-ice cover, such that surface warming leads to an uptake of CO 2 and vice versa, while convective overturning within the sea-ice brines dominate at sites characterized by comparatively thin sea-ice cover, such that nighttime surface cooling leads to an uptake of CO 2 to the extent permitted by simultaneous formation of superimposed ice in the lower snow column.

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