Strong El Niño and La Niña precipitation—sea surface temperature sensitivity under a carbon removal scenario

El Niño-Southern Oscillation-induced tropical Pacific precipitation anomalies have global impacts and will intensify under greenhouse warming, but the potential for mitigating these changes is less understood. Here, we identify distinct hysteresis features in the precipitation-sea surface temperatur...

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Bibliographic Details
Published in:Communications earth & environment 2024-12, Vol.5 (1), p.774-16, Article 774
Main Authors: Liu, Chao, An, Soon-Il, Yan, Zixiang, Kim, Soong-Ki, Paik, Seungmok
Format: Article
Language:English
Subjects:
704/106/35/823
704/106/829/2737
Anomalies
Carbon
Carbon dioxide
Climate change
Climate change mitigation
Convection
Earth and Environmental Science
Earth Sciences
El Nino
Environment
Equatorial regions
Global warming
Greenhouse effect
Hysteresis
Intertropical convergence zone
Intertropical convergent zones
La Nina
Mathematical models
Ocean circulation
Ocean currents
Oceanic convection
Precipitation
Sea surface temperature
Sensitivity analysis
Southern Oscillation
Water circulation
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Summary:El Niño-Southern Oscillation-induced tropical Pacific precipitation anomalies have global impacts and will intensify under greenhouse warming, but the potential for mitigating these changes is less understood. Here, we identify distinct hysteresis features in the precipitation-sea surface temperature sensitivity between strong El Niño and La Niña phases using a large ensemble carbon removal numerical simulation. The strong El Niño precipitation sensitivity exhibits a century-scale hysteretic enhancement and eastward shift, mainly due to modulated deep convection anomalies by the Intertropical Convergence Zone via cloud-longwave feedback. Instead, the strong La Niña counterpart is concentrated toward the equator, mostly in the central-western Pacific, with a shorter hysteresis period of a few decades. This primarily involves changes in shallow convection and surface thermal structures during La Niña, shaped by global warming-induced upper-ocean circulation changes. The distinct climate change regimes of strong El Niño and La Niña precipitation sensitivity hold important implications for assessing mitigation consequences. The hysteresis in precipitation-sea surface temperature sensitivity differs between strong El Niño and La Niña phases, with El Niño intensifying and shifting eastward due to deep convection, while La Niña is more equator-centered with a shorter hysteresis period, according to a large ensemble simulation of symmetric CO 2 ramp-up and ramp-down pathways.
ISSN:2662-4435
2662-4435
DOI:10.1038/s43247-024-01958-8