Details

Autor(en) / Beteiligte

• Jin, Yuming
• Stephens, Britton B.
• Keeling, Ralph F.
• Morgan, Eric J.
• Rödenbeck, Christian
• Patra, Prabir K.
• Long, Matthew C.

Titel

Seasonal Tropospheric Distribution and Air‐Sea Fluxes of Atmospheric Potential Oxygen From Global Airborne Observations

Ist Teil von

• Global biogeochemical cycles, 2023-10, Vol.37 (10)

Ort / Verlag

Washington: Blackwell Publishing Ltd

Erscheinungsjahr

2023

Quelle

Wiley Online Library Journals【Remote access available】

Beschreibungen/Notizen

• Abstract Seasonal change of atmospheric potential oxygen (APO ∼ O 2  + CO 2 ) is a tracer for air‐sea O 2 flux with little sensitivity to the terrestrial exchange of O 2 and CO 2 . In this study, we present the tropospheric distribution and inventory of APO in each hemisphere with seasonal resolution, using O 2 and CO 2 measurements from discrete airborne campaigns between 2009 and 2018. The airborne data are represented on a mass‐weighted isentropic coordinate ( M θe ) as an alternative to latitude, which reduces the noise from synoptic variability in the APO cycles. We find a larger seasonal amplitude of APO inventory in the Southern Hemisphere relative to the Northern Hemisphere, and a larger amplitude in high latitudes (low M θe ) relative to low latitudes (high M θe ) within each hemisphere. With a box model, we invert the seasonal changes in APO inventory to yield estimates of air‐sea flux cycles at the hemispheric scale. We found a larger seasonal net outgassing of APO in the Southern Hemisphere (518 ± 52.6 Tmol) than in the Northern Hemisphere (342 ± 52.1 Tmol). Differences in APO phasing and amplitude between the hemispheres suggest distinct physical and biogeochemical mechanisms driving the air‐sea O 2 fluxes, such as fall outgassing of photosynthetic O 2 in the Northern Hemisphere, possibly associated with the formation of the seasonal subsurface shallow oxygen maximum. We compare our estimates with four model‐ and observation‐based products, identifying key limitations in these products or in the tools used to create them. Plain Language Summary A better understanding of the air‐sea O 2 fluxes facilitates the study of marine productivity, global carbon cycle and ocean heat transport. Seasonal air‐sea exchange of O 2 has been estimated by combining precise measurements of atmospheric O 2 and CO 2 into atmospheric potential oxygen (APO ∼ O 2  + CO 2 ). Using APO observations from nine global airborne campaigns between 2009 and 2018, we resolved the seasonal cycle of atmospheric APO concentration in multiple pressure and latitude bands, yielding estimates of the tropospheric APO inventory, and area‐integrated air‐sea APO flux of each hemisphere. To a first approximation, the ocean is a source of APO in the spring and summer but a sink in the fall and winter, tracking the seasonal warming and cooling of the ocean as well as different ocean biogeochemistry and ventilation regimes. In addition, these cycles show clear asymmetry between hemispheres and display a progressive shift in the seasonal phase and amplitude across latitudes. It is therefore important to understand the physical and biogeochemical processes that lead to these differences. Key Points From airborne atmospheric potential oxygen (APO) data, we resolve seasonal cycles of APO and hemisphere‐integrated air‐sea APO fluxes We resolved clear hemispheric differences in the seasonal amplitude and shape of the APO flux cycles This study identifies limitations in the Garcia and Keeling O 2 flux climatology, pointing to the need for an improved climatology