Drivers of Air‐Sea CO2 Flux in the Subantarctic Zone Revealed by Time Series Observations

The subantarctic zone is an important region in the Southern Ocean with respect to its influence on air‐sea CO2 exchange and the global ocean carbon cycle. However, understanding of the magnitude and drivers of the flux are still being refined. Using observations from the Southern Ocean Time Series...

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Bibliographic Details
Published in:Global biogeochemical cycles 2024-01, Vol.38 (1), p.n/a
Main Authors: Yang, Xiang, Wynn‐Edwards, Cathryn A., Strutton, Peter G., Shadwick, Elizabeth H.
Format: Article
Language:English
Subjects:
Antarctic Oscillation
Biological activity
Biological uptake
Carbon
Carbon cycle
Carbon dioxide
Carbon dioxide exchange
Carbon dioxide flux
carbon flux
Carbon sinks
Carbon uptake
Eddies
Mass movement
Mesoscale processes
Oceans
Partial pressure
Primary production
primary productivity
Regression models
Salinity
Sea surface
Seasonal variability
Seasonal variation
Seasonal variations
Seasons
Southern Annular Mode
Southern Ocean Time Series
subantarctic zone
Time lag
Time series
Water masses
Wind speed
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Summary:The subantarctic zone is an important region in the Southern Ocean with respect to its influence on air‐sea CO2 exchange and the global ocean carbon cycle. However, understanding of the magnitude and drivers of the flux are still being refined. Using observations from the Southern Ocean Time Series (SOTS) station (∼47°S, 142°E) and auxiliary data, we developed a multiple linear regression model to compute the sea surface partial pressure of CO2 (pCO2) over the past two decades. The mean amplitude of the pCO2 seasonal cycle between 2004 and 2021 was 44 μatm (range 30–54 μatm). Summer minima ranged from 310 to 370 μatm and winter maxima were near equilibrium with the atmosphere. The non‐thermal (i.e., biological processes and mixing) contribution to the seasonal variability in pCO2 was several times larger than the thermal contribution. The SOTS region acted as a net carbon sink at annual time scales, with mean magnitude of 6.0 mmol m−2 d−1. The positive phase of the Southern Annular Mode (SAM) increased ocean carbon uptake primarily through an increase in wind speed at zero time lag. Increased surface pCO2 was correlated with a positive SAM with a lag of 4 months, mainly due to reduced biological uptake and increased mixing. During the autotrophic season, pCO2 was predominantly impacted by primary productivity, whereas water mass movement, inferred by temperature and salinity anomalies, had a larger impact on the heterotrophic season. In general, mesoscale processes such as eddies and frontal movement impact the local biogeochemical features more than the SAM. Key Points An MLR model was built based on Southern Ocean Time Series data, to simulate surface pCO2 in the Australian sector subantarctic zone over the last 20 years Biological productivity controls the seasonal variability of pCO2 and drives a net carbon sink over two decades Mesoscale processes, and to a lesser extent, the Southern Annular Mode, drive local air‐sea CO2 flux variability
ISSN:0886-6236
1944-9224
DOI:10.1029/2023GB007766