The North Atlantic Biological Pump: INSIGHTS FROM THE OCEAN OBSERVATORIES INITIATIVE IRMINGER SEA ARRAY

The North Atlantic Biological Pump INSIGHTS FROM THE OCEAN OBSERVATORIES INITIATIVE IRMINGER SEA ARRAY

The biological pump plays a key role in the global carbon cycle by transporting photosynthetically fixed organic carbon into the deep ocean, where it can be sequestered from the atmosphere over annual or longer time scales if exported below the winter ventilation depth. In the subpolar North Atlanti...

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Bibliographic Details
Published in:Oceanography (Washington, D.C.) Vol. 31; no. 1; pp. 42 - 49
Main Authors: Palevsky, Hilary I., Nicholson, David P.
Format: Journal Article
Language:English
Published: Rockville The Oceanography Society 01-03-2018
Oceanography Society
Subjects:
Autotrophy
Biogeochemistry
Blooms
Carbon cycle
Carbon sequestration
Diatoms
Forces (mechanics)
Membrane transport proteins
Metalimnion
Mixed layer
Observatories
Oceans
Organic carbon
Oxygen
Plankton
Regions
Respiration
Seas
Seasonal thermocline
Seasons
SPECIAL ISSUE ON THE OCEAN OBSERVATORIES INITIATIVE
Spring
Temperature (air-sea)
Thermocline
Thermoclines
Ventilation
Ventilation systems
Winter
Irminger Sea
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Summary:The biological pump plays a key role in the global carbon cycle by transporting photosynthetically fixed organic carbon into the deep ocean, where it can be sequestered from the atmosphere over annual or longer time scales if exported below the winter ventilation depth. In the subpolar North Atlantic, carbon sequestration via the biological pump is influenced by two competing forces: a spring diatom bloom that features large, fast-sinking biogenic particles, and deep winter mixing that requires particles to sink much further than in other ocean regions to escape winter ventilation. We synthesize biogeochemical sensor data from the first two years of operations at the Ocean Observatories Initiative Irminger Sea Array of moorings and gliders (September 2014–July 2016), providing the first simultaneous year-round observations of biological carbon cycling processes in both the surface ocean and the seasonal thermocline in this critical but previously undersampled region. These data show significant mixed layer net autotrophy during the spring bloom and significant respiration in the seasonal thermocline during the stratified season (~5.9 mol C m−2remineralized between 200 m and 1,000 m). This respired carbon is subsequently ventilated during winter convective mixing (>1,000 m), a significant reduction in potential carbon sequestration. This highlights the importance of year-round observations to accurately constrain the biological pump in the subpolar North Atlantic, as well as other high-latitude regions that experience deep winter mixing.
ISSN:1042-8275
2377-617X
DOI:10.5670/oceanog.2018.108