Table_2_Net Community Production and Carbon Exchange From Winter to Summer in the Atlantic Water Inflow to the Arctic Ocean.DOCX

The eastern Fram Strait and area north of Svalbard, are influenced by the inflow of warm Atlantic water, which is high in nutrients and CO 2 , influencing the carbon flux into the Arctic Ocean. However, these estimates are mainly based on summer data and there is still doubt on the size of the net o...

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Bibliographic Details
Main Authors: Melissa Chierici, Maria Vernet, Agneta Fransson, Knut Yngve Børsheim
Format: Dataset
Language:unknown
Published: 2019
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
Atlantic water
sea ice melt water
Fram Strait and Svalbard shelf
ocean CO2 sink
denitrification
primary production
ocean acidification
Arctic
Arctic Ocean
Svalbard
Fram Strait
Ocean acidification
Sea ice
Spitsbergen
Online Access:https://doi.org/10.3389/fmars.2019.00528.s002
https://figshare.com/articles/Table_2_Net_Community_Production_and_Carbon_Exchange_From_Winter_to_Summer_in_the_Atlantic_Water_Inflow_to_the_Arctic_Ocean_DOCX/9789593
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Summary:The eastern Fram Strait and area north of Svalbard, are influenced by the inflow of warm Atlantic water, which is high in nutrients and CO 2 , influencing the carbon flux into the Arctic Ocean. However, these estimates are mainly based on summer data and there is still doubt on the size of the net ocean Arctic CO 2 sink. We use data on carbonate chemistry and nutrients from three cruises in 2014 in the CarbonBridge project (January, May, and August) and one in Fram Strait (August). We describe the seasonal variability and the major drivers explaining the inorganic carbon change (C DIC ) in the upper 50 m, such as photosynthesis (C BIO ), and air-sea CO 2 exchange (C EXCH ). Remotely sensed data describes the evolution of the bloom and net community production. The focus area encompasses the meltwater-influenced domain (MWD) along the ice edge, the Atlantic water inflow (AWD), and the West Spitsbergen shelf (SD). The C BIO total was 2.2 mol C m –2 in the MWD derived from the nitrate consumption between January and May. Between January and August, the C BIO was 3.0 mol C m –2 in the AWD, thus C BIO between May and August was 0.8 mol C m –2 . The ocean in our study area mainly acted as a CO 2 sink throughout the period. The mean CO 2 sink varied between 0.1 and 2.1 mol C m –2 in the AWD in August. By the end of August, the AWD acted as a CO 2 source of 0.7 mol C m –2 , attributed to vertical mixing of CO 2 -rich waters and contribution from respiratory CO 2 as net community production declined. The oceanic CO 2 uptake (C EXCH ) from the atmosphere had an impact on C DIC between 5 and 36%, which is of similar magnitude as the impact of the calcium carbonate (CaCO 3 , C CALC ) dissolution of 6–18%. C CALC was attributed to be caused by a combination of the sea-ice ikaite dissolution and dissolution of advected CaCO 3 shells from the south. Indications of denitrification were observed, associated with sea-ice meltwater and bottom shelf processes. C BIO played a major role (48–89%) for the impact on C DIC .

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