Synoptic evaluation of carbon cycling in the Beaufort Sea during summer: Contrasting river inputs, ecosystem metabolism and air-sea CO₂ fluxes.

La transcription des symboles et des caractères spéciaux utilisés dans la version originale de ce résumé n’a pas été possible en raison de limitations techniques. La version correcte de ce résumé peut être lue en PDF. The accelerated decline in Arctic sea ice and an ongoing trend toward more energet...

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Bibliographic Details
Published in:Biogeosciences
Main Authors: Forest, Alexandre, Coupel, Pierre, Else, Brent G. T., Nahavandian Esfahani, Somayeh, Lansard, Bruno, Raimbault, Patrick, Papakyriakou, Tim N., Gratton, Yves, Fortier, Louis, Tremblay, Jean-Éric, Babin, Marcel
Format: Article in Journal/Newspaper
Language:English
Published: 2014
Subjects:
air-sea interaction
carbon cycle
carbon dioxide
mixed layer
net primary production
respiration
summer
Arctic
Arctic Ocean
Mackenzie River
Wind River
ArcticNet
Beaufort Sea
Mackenzie river
Sea ice
Online Access:https://espace.inrs.ca/id/eprint/3757/
https://espace.inrs.ca/id/eprint/3757/1/P2520.pdf
https://doi.org/10.5194/bg-11-2827-2014
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Summary:La transcription des symboles et des caractères spéciaux utilisés dans la version originale de ce résumé n’a pas été possible en raison de limitations techniques. La version correcte de ce résumé peut être lue en PDF. The accelerated decline in Arctic sea ice and an ongoing trend toward more energetic atmospheric and oceanic forcings are modifying carbon cycling in the Arctic Ocean. A critical issue is to understand how net community production (NCP; the balance between gross primary production and community respiration) responds to changes and modulates air-sea CO2 fluxes. Using data collected as part of the ArcticNet-Malina 2009 expedition in the southeastern Beaufort Sea (Arctic Ocean), we synthesize information on sea ice, wind, river, water column properties, metabolism of the planktonic food web, organic carbon fluxes and pools, as well as air-sea CO2 exchange, with the aim of documenting the ecosystem response to environmental changes. Data were analyzed to develop a non-steady-state carbon budget and an assessment of NCP against air-sea CO2 fluxes. During the field campaign, the mean wind field was a mild upwelling-favorable wind (∼ 5 km hg-1) from the NE. A decaying ice cover (< 80% concentration) was observed beyond the shelf, the latter being fully exposed to the atmosphere. We detected some areas where the surface mixed layer was net autotrophic owing to high rates of primary production (PP), but the ecosystem was overall net heterotrophic. The region acted nonetheless as a sink for atmospheric CO2, with an uptake rate of g-2.0 ± 3.3 mmol C mg-2 dg-1 (mean ± standard deviation associated with spatial variability). We attribute this discrepancy to (1) elevated PP rates (> 600 mg C mg-2 dg -1) over the shelf prior to our survey, (2) freshwater dilution by river runoff and ice melt, and (3) the presence of cold surface waters offshore. Only the Mackenzie River delta and localized shelf areas directly affected by upwelling were identified as substantial sources of CO2 to the atmosphere (> 10 ...

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