Abstract
The Southern Ocean (SO) played a fundamental role in the deglacial climate system by exchanging carbon-rich deep ocean water with the surface. The contribution of the SO’s physical mechanisms toward improving our understanding of SO upwelling’s dynamical changes is developing. Here, we investigated the simulated transient SO atmosphere, ocean, and sea ice evolution during the last deglaciation in a fully coupled Earth system model. Our results showed that decreases in SO upwelling followed the weakening of the Southern Hemisphere surface westerlies, wind stress forcing, and Antarctic sea ice coverage from the Last Glacial Maximum to the Heinrich Stadial 1 and the Younger Dryas. Our results support the idea that the SO upwelling is primarily driven by wind stress forcing. However, during the onset of the Holocene, SO upwelling increased while the strength of the wind stress decreased. The Antarctic sea ice change controlled the salt and freshwater fluxes, ocean density, and buoyancy flux, thereby influencing the SO’s dynamics. Our study highlighted the dynamic linkage of the Southern Hemisphere westerlies, ocean, and sea ice in the SO’s latitudes. Furthermore, it emphasized that zonal wind stress forcing and buoyancy forcing control by sea ice together regulate the change in the SO upwelling.
Highlights
IntroductionThe last deglaciation from 21 to 9 kyr BP (before present) offers a case study for the most recent natural global warming process
The last deglaciation from 21 to 9 kyr BP offers a case study for the most recent natural global warming process
Simulated upwelling (black; units are in Sverdrup (Sv)) and the maximum zonal wind stress (≈46◦ S; red, dashed; units are in dyne per square centimeter) was smoothed using a Savitsky–Golay filter with a third-order polynomial convolution at the Indian Ocean (IO) (c,g) and the Pacific Ocean (PO) sector (d,h) respectively
Summary
The last deglaciation from 21 to 9 kyr BP (before present) offers a case study for the most recent natural global warming process. This period involved a transient climate evolution from a colder to a warmer world. The Southern Ocean (SO) plays a pivotal role in controlling the variation in atmospheric CO2 concentrations over glacial–interglacial cycles [2]. It ventilates a significant part of the global ocean and acts as a window for the return of carbon-rich deep ocean water to the surface. Understanding the physical mechanisms that determined the temporal and spatial change in SO upwelling throughout the Earth’s history will improve our comprehension of the response of the SO’s dynamics in future climate projections and the associated difference in atmospheric CO2 concentrations
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