Litcius/Paper detail

Diverging Fates of the Pacific Ocean Oxygen Minimum Zone and Its Core in a Warming World

Julius Busecke, Laure Resplandy, Sam Ditkovsky, Jasmin G. John

2022AGU Advances88 citationsDOIOpen Access PDF

Abstract

Abstract Global ocean oxygen loss is projected to persist in the future, but Earth system models (ESMs) have not yet provided a consistent picture of how it will influence the largest oxygen minimum zone (OMZ) in the tropical Pacific. We examine the change in the Pacific OMZ volume in an ensemble of ESMs from the CMIP6 archive, considering a broad range of oxygen (O 2 ) thresholds relevant to biogeochemical cycles and ecosystems (5–160 µmol/kg). Despite OMZ biases in the historical period of the simulations, the ESM ensemble projections consistently fall into three regimes across ESMs: an expansion of low oxygenated waters (+0.8 [0.6, 1.0] × 10 16 m 3 /century for O 2 ≤ 120 µmol/kg, ESM median and interquartile range); a slight contraction of the OMZ core although more uncertain across ESMs (−0.1 [−0.5, 0.0] × 10 16 m 3 /century for O 2 ≤ 20 µmol/kg); and at the transition from contraction to expansion regimes, a spatial redistribution but near‐zero change in the volume of hypoxic waters (0.0 [−0.3, +0.1] × 10 16 m 3 /century for O 2 ≤ 60 µmol/kg). Changes in circulation and biology dictate the shift from expansion to contraction. Specifically, reduced subtropical ventilation controls the expansion of low oxygenated waters, while a combination of circulation and biological changes explains the contraction of the core (likely changes in mixing, reduced intermediate ventilation and oxygen demand). Increased model complexity (e.g., ecosystem dynamics and equatorial circulation) likely stabilize the OMZ response, suggesting that future changes might lie in the lower bound of current projections. The expansion of low oxygenated waters which delimit the optimum habitat of numerous marine species would severely impact ecosystems and ecosystem services.

Topics & Concepts

Oxygen minimum zoneOxygenClimate changeBiogeochemical cycleEnvironmental scienceEcosystemGlobal warmingOceanographyChemistryAtmospheric sciencesClimatologyEcologyGeologyBiologyEnvironmental chemistryOrganic chemistryMarine and coastal ecosystemsOcean Acidification Effects and ResponsesOceanographic and Atmospheric Processes