FN Archimer Export Format PT J TI Poleward shift in the Southern Hemisphere westerly winds synchronous with the deglacial rise in CO2 BT AF Gray, William R. de Lavergne, Casimir Jnglin Wills, Robert C. Menviel, Laurie Spence, Paul Holzer, Mark Kageyama, Masa Michel, Elisabeth AS 1:1;2:2;3:3,4;4:5,6;5:6,7,8;6:9;7:1;8:1; FF 1:;2:;3:;4:;5:;6:;7:;8:; C1 Laboratoire des Sciences du Climat et de l’Environnement (LSCE/IPSL) Université Paris‐Saclay Gif‐sur‐Yvette ,France LOCEAN Laboratory Sorbonne Université‐CNRS‐IRD‐MNHN Paris, France Institute for Atmospheric and Climate Science ETH Zurich 8092 Zurich ,Switzerland Department of Atmospheric Sciences University of Washington Seattle WA 98195, USA Climate Change Research Centre University of New South Wales NSW 2052 Sydney, Australia The Australian Centre for Excellence in Antarctic Science University of Tasmania Hobart Tasmania 7001 ,Australia Institute for Marine and Antarctic Studies University of Tasmania Hobart, Australia Australian Antarctic Partnership Program University of Tasmania Hobart ,Australia School of Mathematics and Statistics University of New South Wales NSW 2052 Sydney, Australia C2 UNIV PARIS SACLAY, FRANCE UNIV SORBONNE, FRANCE ETH ZURICH, SWITZERLAND UNIV WASHINGTON, USA UNIV NEW S WALES, AUSTRALIA UNIV TASMANIA, AUSTRALIA UNIV TASMANIA, AUSTRALIA UNIV TASMANIA, AUSTRALIA UNIV NEW S WALES, AUSTRALIA IF 3.5 TC 7 UR https://archimer.ifremer.fr/doc/00842/95397/103174.pdf https://archimer.ifremer.fr/doc/00842/95397/103175.csv https://archimer.ifremer.fr/doc/00842/95397/103176.csv https://archimer.ifremer.fr/doc/00842/95397/103177.csv https://archimer.ifremer.fr/doc/00842/95397/103178.pdf LA English DT Article CR MD 125 / SWIFT BIS-CARHOT MD 189 / INDIEN SUD 2 BO Marion Dufresne AB The Southern Hemisphere westerly winds influence deep ocean circulation and carbon storage. While the westerlies are hypothesised to play a key role in regulating atmospheric CO2 over glacial-interglacial cycles, past changes in their position and strength remain poorly constrained. Here, we use a compilation of planktic foraminiferal δ18O from across the Southern Ocean and emergent relationships within an ensemble of climate models to reconstruct changes in the Southern Hemisphere surface westerlies over the last deglaciation. We infer a 4.8° (2.9-7.1°, 95% confidence interval) equatorward shift and about a 25% weakening of the westerlies during the Last Glacial Maximum (LGM; 20 ka) relative to the mid-Holocene (6.5 ka). Climate models from the Palaeoclimate Modelling Intercomparison Project substantially underestimate this inferred equatorward wind shift. According to our reconstruction, the poleward shift in the westerlies over deglaciation closely mirrors the rise in atmospheric CO2 (R2=0.98). Experiments with a 0.25° resolution ocean-sea-ice-carbon model suggest that shifting the westerlies equatorward reduces the overturning rate of the ocean below 2 km depth, leading to a suppression of CO2 outgassing from the polar Southern Ocean. Our results support a role for the westerly winds in driving the deglacial CO2 rise, and suggest outgassing of natural CO2 from the Southern Ocean is likely to increase as the westerlies shift poleward due to anthropogenic warming. Key Points we use planktic foraminiferal δ18O and climate models to infer deglacial changes in the Southern Hemisphere surface westerlies we estimate the westerlies were ∼5° equatorward and ∼25% weaker at the LGM; their poleward shift over deglaciation mirrors the rise in CO2 experiments with a 1/4° ocean-sea-ice-carbon model indicate increased oceanic carbon storage with equatorward shifted westerlies Plain Language Summary The mid-latitudes of the Southern Hemisphere are characterised by a band of strong westerly winds. These winds play an important role in driving the circulation of the deep ocean and are thought to influence the oceans’ ability to store carbon. Understanding how the westerlies have varied in the past is challenging as we have few methods to track the winds directly. Here we use oxygen isotopes in foraminiferal shells to track changes in the broad-scale pattern of sea surface temperature across the Southern Ocean, which we link to changes in the winds using climate models. We find the westerly winds were displaced around 5° equatorward during the cold climate of the last ice age, and that the poleward shift in the winds we observe as the earth warmed out of the ice age bears an uncanny resemblance to the increase in atmospheric CO2. We then force the winds in a climate model towards the equator in a similar manner to the shift we observe in the ice age, and find the model stores more carbon in the ocean. Our results support a link between shifts in the Southern Hemisphere westerly winds and atmospheric CO2. PY 2023 PD JUN SO Paleoceanography And Paleoclimatology SN 2572-4517 PU American Geophysical Union (AGU) VL 38 IS 7 UT 001021050700001 DI 10.1029/2023PA004666 ID 95397 ER EF