Evolution of oxygen and stratification and their relationship in the North Pacific Ocean in CMIP6 Earth system models
Novi, Lyuba; Bracco, Annalisa; Ito, Takamitsu; Takano, Yohei ORCID: https://orcid.org/0000-0001-7984-8810. 2024 Evolution of oxygen and stratification and their relationship in the North Pacific Ocean in CMIP6 Earth system models. Biogeosciences, 21 (17). 3985-4005. https://doi.org/10.5194/bg-21-3985-2024
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Abstract/Summary
This study examines the linkages between the upper-ocean (0–200 m) oxygen (O2) content and stratification in the North Pacific Ocean using four Earth system models (ESMs), an ocean hindcast simulation, and an ocean reanalysis. The trends and variability in oceanic O2 content are driven by the imbalance between physical supply and biological demand. Physical supply is primarily controlled by ocean ventilation, which is responsible for the transport of O2-rich surface waters to the subsurface. Isopycnic potential vorticity (IPV), a quasi-conservative tracer proportional to density stratification that can be evaluated from temperature and salinity measurements, is used herein as a dynamical proxy for ocean ventilation. The predictability potential of the IPV field is evaluated through its information entropy. The results highlight a strong O2–IPV connection and somewhat higher (as compared to the rest of the basin) predictability potential for IPV across the tropical Pacific, where the El Niño–Southern Oscillation occurs. This pattern of higher predictability and strong anticorrelation between O2 and stratification is robust across multiple models and datasets. In contrast, IPV at mid-latitudes has low predictability potential and its center of action differs from that of O2. In addition, the locations of extreme events or hotspots may or may not differ between the two fields, with a strong model dependency, which persists in future projections. On the one hand, these results suggest that it may be possible to monitor ocean O2 in the tropical Pacific based on a few observational sites co-located with the more abundant IPV measurements; on the other, they lead us to question the robustness of the IPV–O2 relationship in the extratropics. The proposed framework helps to characterize and interpret O2 variability in relation to physical variability and may be especially useful in the analysis of new observation-based data products derived from the BGC-Argo float array in combination with the traditional but far more abundant Argo data.
Item Type: | Publication - Article |
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Digital Object Identifier (DOI): | https://doi.org/10.5194/bg-21-3985-2024 |
ISSN: | 17264170 |
Date made live: | 13 Sep 2024 12:51 +0 (UTC) |
URI: | https://nora.nerc.ac.uk/id/eprint/536865 |
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