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Disentangling the mechanisms of equatorial Pacific climate change

Sarah M. Kang, Yechul Shin, Hanjun Kim, Shang‐Ping Xie, Shineng Hu

2023Science Advances31 citationsDOIOpen Access PDF

Abstract

Most state-of-art models project a reduced equatorial Pacific east-west temperature gradient and a weakened Walker circulation under global warming. However, the causes of this robust projection remain elusive. Here, we devise a series of slab ocean model experiments to diagnostically decompose the global warming response into the contributions from the direct carbon dioxide (CO 2 ) forcing, sea ice changes, and regional ocean heat uptake. The CO 2 forcing dominates the Walker circulation slowdown through enhancing the tropical tropospheric stability. Antarctic sea ice changes and local ocean heat release are the dominant drivers for reduced zonal temperature gradient over the equatorial Pacific, while the Southern Ocean heat uptake opposes this change. Corroborating our model experiments, multimodel analysis shows that the models with greater Southern Ocean heat uptake exhibit less reduction in the temperature gradient and less weakening of the Walker circulation. Therefore, constraining the tropical Pacific projection requires a better insight into Southern Ocean processes.

Topics & Concepts

ClimatologyForcing (mathematics)Environmental scienceOcean heat contentOcean general circulation modelWalker circulationEffects of global warming on oceansClimate changeOceanographySea surface temperatureClimate modelOcean currentGeneral Circulation ModelGlobal warmingGeologyClimate variability and modelsArctic and Antarctic ice dynamicsOceanographic and Atmospheric Processes
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