Main

The Antarctic Circumpolar Current (ACC), driven by the interplay among Southern Westerly Winds (SWW), buoyancy forcing and bathymetry1, is the largest ocean current on Earth. It actively regulates the transport of heat, moisture, carbon and nutrients between the Southern Ocean and the low-latitude regions, thus substantially influencing atmospheric CO2 and global climate1. To assess the future response of the ACC to ongoing climate warming and its impacts on Antarctic Ice Sheet dynamics, global circulation and climate2, it is critical to unravel the timing and processes that led to the development of the modern-like deep-reaching and homogeneous ACC (circumpolar flow extending from the surface to the seafloor), a topic that has been debated for more than four decades3,4,5,6,7,8,9,10.

One precondition for the inception of the ACC is the deep tectonic opening of two gateways that blocked circumpolar flow in the geological past: the Tasmanian Gateway and the Drake Passage (Fig. 1). Tectonic deepening of the Tasmanian Gateway has been constrained between 33.5 and 30.0 million years ago (Ma) (ref. 11), which matches recent reconstructions of a deep eastward flow from the South Indian Ocean to the South Pacific Ocean at 30 Ma, as the Tasmanian Gateway aligned with the SWW8. However, estimates for the deep opening of Drake Passage are still debated and range from the Oligocene (34 Ma) to the late Miocene (12 Ma) (refs. 5,7,9,12). Furthermore, recent work has questioned whether the tectonic opening of gateways alone is sufficient to initiate a deep-reaching and vigorous ACC similar to today’s13. Moreover, eddy-resolving ocean model simulations show that even enhanced SWW are not able to generate a modern-like ACC when both gateways are open, suggesting that buoyancy forcing plays a primary control over the ACC transport14,15.

Fig. 1: Southern Ocean circulation and core locations.
figure 1

a, Map of current speeds in the Southern Ocean and location of our study sites (yellow dots): DSDP 278 and ODP 744. Warmer red colours represent higher current speeds. b, ACC fronts (mean positions), Subantarctic Front (yellow), Polar Front (red) and Southern ACC Front (blue). For information of each site and references, see Extended Data Fig. 6. DP, Drake Passage; TG, Tasmanian Gateway; KP, Kerguelen Plateau; MR, Macquarie Ridge. Data in b for the ACC front, Subantarctic Front, Polar Front and Southern ACC Front from ref. 48. Panel a adapted with permission from ref. 1, Springer Nature Limited. Panel b created with Ocean Data View49.

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Diagnostic features of the modern ACC

In light of the ambiguous evidence for the inception of the modern-like ACC, we present new geological data to constrain two of its diagnostic features: (1) a homogeneous neodymium (Nd) isotope signature of Circumpolar Deep Waters (CDW) across the Southern Ocean (compilation from ref. 16 and references therein) and (2) a deep-reaching strong flow (flow speed > 10 cm s–1) (ref. 17).

Our new records were generated from two well-dated sediment cores (Methods and Extended Data Figs. 1 and 2) recovered at Deep Sea Drilling Project (DSDP) Site 278 located in the Southern Emerald Basin (Pacific sector of the Southern Ocean; 56° 33.42′ S, 160° 04.29′ E, 3,675 m water depth)18 and Ocean Drilling Program (ODP) Site 744 located on the Southern Kerguelen Plateau (Indian sector of the Southern Ocean; 61° 34.66′ S, 80° 35.43′ E, 2,307 m water depth)19 (Fig. 1). Both sites were persistently positioned within the main pathway of the ACC since the early Oligocene (31 Ma) and cover the depth range of the modern CDW (2,500 and 3,500 m, respectively)10,20.

Fossil fish debris from Sites 744 and 278 robustly preserved a seawater Nd isotope signature10,20 (Supplementary Information and Extended Data Figs. 3 and 4), and results can be used to reconstruct water-mass homogeneity along the ACC flow path (εNd(t) denotes the time-corrected deviation of a measured 143Nd/144Nd ratio from the chondritic uniform reservoir in parts per 10,000 (ref. 21); Methods). Mean sortable silt (\(\overline{{\rm{SS}}}\)) size (10–63 μm) of terrigenous sediment fractions, can be used to reconstruct bottom flow speed22 (Supplementary Information and Extended Data Fig. 5). Combined, the proxies offer a unique and robust approach to determine the initiation of the modern-like, deep-reaching and vigorous ACC.

Onset of a homogeneous circumpolar Nd isotope fingerprint

At Site 744 (Southern Kerguelen Plateau; Fig. 1), fish debris εNd(t) values range from –9.9 ± 0.1 to –7.8 ± 0.2 between the early Miocene (23.5 Ma) and the early Pleistocene (1.2 Ma) (Fig. 2b). These values are in good agreement with published Nd isotope palaeorecords from the South Atlantic and Indian oceans during the same period (εNd(t) = –7 to –10) (Fig. 3 and Extended Data Fig. 6), suggesting an efficient exchange of deep waters between the Atlantic and the Indian sectors of the Southern Ocean since the Oligocene20,23,24. Modern CDW show a similar range in Nd isotope compositions (εNd = –8.3 ± 1.5, n = 158; compilation from ref. 16 and references therein) (Fig. 2b), implying that Site 744 was bathed by a deep water mass resembling modern CDW εNd values throughout the study interval.

Fig. 2: Evolution of global climate, Antarctic Circumpolar Current and Southern Ocean climate over the past 31 Myr.
figure 2

a, Global benthic foraminiferal δ18O records41. Antarctic sea-ice increase is based on refs. 32,42. b, εNd(t) of fish debris at DSDP Site 278. Site 278 εNd(t) from 30.9 to 21.8 Ma are from ref. 10. εNd(t) of fish debris at ODP Site 744. Site 744 εNd(t) from 30.9 to 23.6 Ma are from ref. 20. Error envelopes and error bars represent instrumental uncertainty (2σ). Present-day CDW εNd endmember along the ACC is shown in grey, compilation by ref. 16 and references therein. c, New mean sortable silt record from DSDP Site 278 (\(\overline{{\rm{SS}}}\)) (analytical error ±3%) and PS97/093-2 (pink stars) from ref. 29. d, Calculated ACC flow speeds from DSDP Site 278 (V) and PS97/093-2 (pink stars) (error estimates ±12.5%)22. Modern-like mean \(\overline{{\rm{SS}}}\) values along the ACC are based on cores located in the DP29,30,31. e, SWW evolution in Southwest Australia based on Mg/Al data (n = 140; analytical error less than 5%) from IODP U1516 (ref. 44). f, Sea surface temperature (SST) from ODP Site 1168 (refs. 39,50). MMCT, middle Miocene Climatic Transition; NH, Northern Hemisphere; SH, Southern Hemisphere.

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Fig. 3: Comparison of fish debris εNd(t) data from DSDP Site 278 and ODP Site 744 with other authigenic Nd records (fish debris and ferromanganese crusts) from the Atlantic, Indian and Pacific oceans.
figure 3

For site information, locations, designed endmembers and references, see Extended Data Fig. 6.

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By contrast, εNd(t) values at Site 278 in the Southwest Pacific are consistently more radiogenic (εNd(t) ≈ –6.0 ± 0.2 to –7.4 ± 0.3) than published palaeorecords from Atlantic and Indian sectors of the Southern Ocean, as well as the modern-like CDW εNd values16 until the middle Miocene (15 Ma) (Figs. 2b and 3). This indicates a fundamentally different deep ocean circulation pattern in the Pacific sector of the Southern Ocean until the middle Miocene, compared with today. Our data hence imply the absence of a modern-like efficient deep-water exchange between the Indian and the Pacific sectors of the Southern Ocean during the Oligocene and early Miocene.

Overall, variations in εNd(t) values at Site 744 are controlled by the admixture of Atlantic (more unradiogenic, lower values) and Pacific (more radiogenic, higher values) waters into CDW, with potential minor influence of Antarctic weathering inputs20. In detail, between the early and middle Miocene (21–14.5 Ma), Nd isotopes at Site 744 evolve towards more unradiogenic values (Fig. 2b). This trend has previously been observed in Nd isotope palaeorecords from the Walvis Ridge (Sites 1262 and 1264)23 and Agulhas Ridge (Site 1090)24 (Extended Data Fig. 6) and been attributed to increased inflow of North Component Water (precursor of North Atlantic Deep Water) into CDW, probably via a stronger Atlantic meridional overturning circulation between the early and middle Miocene23. The fact that absolute Nd isotope values at Kerguelen Site 744 are lower than those observed around the Agulhas Ridge Site 1090 can probably be attributed to entrainment of unradiogenic dissolved Nd from old continental sources in Prydz Bay25.

Between 14.5 and 12.0 Ma, εNd(t) values at Site 744 exhibit a shift towards more radiogenic values (Fig. 2b), probably reflecting increased inflow of Pacific waters to CDW via Drake Passage. This timing coincides with geophysical, geological and geochemical evidence suggesting major tectonic changes in Drake Passage (development of a deep oceanic gateway along the southern Scotia Sea Ridge during the middle Miocene12 and the final opening of a deep oceanic pathway in the central Scotia Sea at 12 Ma7). Hence, our new data, in conjunction with tectonic reconstructions, provide strong evidence for the final establishment of a deep eastward oceanic circulation via Drake Passage at 12 Ma.

The more radiogenic εNd(t) values at Site 278 in the Southwest Pacific between the Oligocene and early Miocene have previously been attributed to a stronger influence of South Pacific Deep Water (εNd(t) ≈ –6)26 in the Southern Emerald Basin because of a shallower and weaker ACC flow entering the Southwest Pacific through the Tasmanian Gateway10. Our new Nd isotope data reveal that this circulation pattern persisted until the middle Miocene (15 Ma), supported by results from climate models showing a limited throughflow of the ACC across the Tasmanian Gateway during the Oligocene in response to a more restricted Australian palaeobathymetry27 and a generally weaker global overturning circulation. The latter has been attributed to weaker SWW as a result of reduced meridional surface temperature gradients during the early to middle Miocene28.

Our εNd(t) values at Site 278 show an increasing influence of unradiogenic Nd in the Southwest Pacific Ocean since the early Miocene (21 Ma) and the convergence with the palaeorecords from the Atlantic/Indian Ocean (Fig. 3) and modern CDW Nd isotope values from the middle Miocene (  15 Ma) (Fig. 2b). Given the palaeodepth (3,500 m) and location of Site 278 in the main pathway of the ACC10, close to the Subantarctic Front, our Nd isotope record can be explained by either (1) an increasing contribution of unradiogenic Nd from Atlantic/Indian deep waters into the deep Southwest Pacific via the Tasmanian Gateway or (2) a weakening influence of radiogenic Nd from Pacific Ocean deep waters. Published Nd isotope data from the Pacific Ocean are inconsistent with a weakening of Pacific deep-water export26 (Fig. 3). We therefore propose an increasing contribution of Atlantic/Indian deep waters, flowing through the Tasmanian Gateway and occupying the deep/abyssal Southwest Pacific, as the source of unradiogenic Nd since the early Miocene. The trend towards more unradiogenic values at Site 278 is consistent with Nd records from the Indian and Atlantic sectors of the Southern Ocean supporting further our hypothesis20,23,24. The εNd(t) values at Site 278 converge with Nd isotope palaeorecords from the Atlantic/Indian Ocean, as well as the modern CDW εNd values16 from the middle Miocene (15 Ma), but consistently only since 12 Ma (Figs. 2b and 3).

Causes of modern-like deep ACC development

The convergence of our two new εNd(t) records from Sites 744 and 278 around 12 Ma marks the emergence of a well-mixed CDW of the ACC and thus the development of a modern-like continuous deep-water connection among all three major oceanic basins of the Southern Ocean (Fig. 2b), which is substantially later than previously suggested3,4,6,8,9. However, was the ACC also characterized by a vigorous, deep-reaching flow similar to that of today from the middle Miocene?

Our new \(\overline{{\rm{SS}}}\) data from Site 278 provide strong evidence that deep ACC speed remains relatively low until at least the late Miocene (10 Ma) (Fig. 2c). On the basis of the calibration of \(\,\overline{{\rm{SS}}}\) for the Scotia–Weddell Sea region22, our data show a mean ACC flow speed of 10 cm s–1 in the Southwest Pacific (Site 278) from the Oligocene to the late Miocene (31–10 Ma; Fig. 2d). This value is two times lower than the ACC flow in Drake Passage (core PS97/093-2)29, and the mean modern deep ACC velocities (20 cm s–1) (refs. 29,30,31) (Fig. 2d). Our data therefore suggest that despite the development of a continuous, deep-water circumpolar connection across the Southern Ocean since the middle Miocene (12 Ma), the ACC never resembled that of the present-day vigorous deep flow speeds until at least the late Miocene (10 Ma). Recent geochemical, sedimentological and micropalaeontological data across both sides of the Tasmanian Gateway support our findings, suggesting the presence of a weak ACC in the Southern Ocean compared with today´s until at least the late Miocene (11 Ma)32,33,34,35,36.

By contrast, our reconstruction of \(\,\overline{{\rm{SS}}}\)-derived flow speeds shows an 50% increase of the deep ACC in the Southwest Pacific (Site 278) during the Pleistocene, converging with deep ACC flow speeds in Drake Passage (PS97/093-2)29 as well as modern-like vigorous deep-reaching ACC values29,30,31 (Fig. 2c,d). This major increase in deep ACC flow speed appears after a hiatus between 10 and 3 Ma, which together with a prominent seismic unconformity in the Emerald Basin have been attributed to erosion associated with a local intensification of the ACC in response to the tectonic opening of the deep gap in Macquarie Ridge at 53.5° S37. Today, 30% of the total transport of the ACC passes through this gap with mean speeds higher than 20 cm s–1 at 3,000 m (ref. 17). To test this hypothesis, we used the high-resolution (1/20° grid spacing) Massachusetts Institute of Technology general circulation model with an open (modern-day) and closed Macquarie Ridge passage (Methods). Our results show the absence of a prominent change in surface and bottom current velocities at Site 278 in response to the tectonic opening of the gap (Extended Data Fig. 7). In fact, bottom current velocities along the eastern flank of the Macquarie Ridge and across the location of Site 278 change by less than 10 cm s–1 due to its opening. Our modelling results therefore argue against the possibility that a regional tectonic event in the Macquarie Ridge could have been a major driver of the observed changes in the deep ACC flow velocities in the Southwest Pacific.

Instead of tectonic changes in the Southern Ocean gateways and Macquarie Ridge region, we propose that climate-driven mechanisms drove the emergence of modern-like strong deep ACC flow. Continued sea surface38,39,40 and deep-water38,41 cooling in the Southern Ocean (Fig. 2f), as well as a large expansion of the Antarctic Ice Sheet38,41 and a more persistent presence of sea ice (Fig. 2a)32,42 since the middle Miocene Climatic Transition led to steepening of Equator–pole temperature gradients39,40 and hence a stronger density gradient14,15 and intensification of the SWW (Fig. 2e)43,44 across the Southern Ocean. This change in buoyancy forcing and wind stress in turn led to substantial intensification of the deep ACC flow. Our hypothesis is supported by our \(\overline{{\rm{SS}}}\) data (Fig. 2c), which despite their low resolution, appear to closely track changes of the SWW as reflected in enhanced precipitation and river run-off in Southwest Australia43,44 (Fig. 2e), sea surface temperature cooling trend offshore Tasmania (Fig. 2f)39 and eddy-resolving ocean model simulations45. Both processes (wind stress and buoyancy forcing) modulated the strength of the ACC, with the buoyancy forcing providing the primary control over the ACC transport as shown by eddy-resolving ocean models14,15. Although the presence of the late Miocene–Late Pliocene hiatus did not allow us to decipher the exact timing of inception of strong modern-like ACC deep flow velocities in the Southwest Pacific, circum-Antarctic sedimentological data provide additional evidence for the onset of a vigorous deep ocean current system in the Southern Ocean since the late Miocene as reflected by the onset and intensification of sediment drift formation46,47. Regardless of the exact timing of the onset of vigorous deep ACC flow, our findings provide solid evidence that deep ACC flow did not resemble modern-like velocities before the late Miocene (10 Ma) and indicate that the emergence of the modern-like vigorous deep ACC was a result of an enhanced density contrast and intensified SWW across the Southern Ocean driven by the increased Antarctic glaciation and sea-ice production.

By providing direct proxy-based evidence for the absence of a vigorous, deep-reaching ACC before 10 Ma, our data challenge long-held inferences that the modern ACC development was controlled solely by the opening of Southern Ocean gateways during and after the Eocene–Oligocene Transition (34 Ma). Furthermore, our findings demonstrate that the development of the ACC did not trigger the Antarctic Ice Sheet expansion during the Eocene–Oligocene Transition. Instead, the onset of the modern-like, deep-reaching ACC was a result of an enhanced density contrast and the intensification of the SWW across the Southern Ocean driven by the increased Antarctic glaciation following the middle Miocene Climatic Optimum. Our results suggest that the development of a strong deep-reaching ACC may have played an active role in global cooling by enhancing the global overturning circulation and subsequent drawdown of atmospheric CO2 that characterized the late Cenozoic climate41.

Methods

Age model

The age model for DSDP Site 278 cores 31R to 26R is from ref. 10. An age–depth model for the DSDP Site 278 cores 25R to 2R (329–100 m below seafloor) was developed from the revision and integration of calcareous nannofossil, marine diatom and radiolarian biostratigraphy, calibrated using The Geologic Time Scale 201251. Our updated age interpretation for the sediments between cores 25R and 2R spans an interval from 21.3 to 0.5 Ma (Extended Data Fig. 1). Detailed discussion on the development of the age model is presented in ref. 10. The age model for the lower Miocene and Pleistocene intervals of ODP Site 744 Hole B was developed from the revision of marine diatom, radiolarian biostratigraphy and magnetostratigraphic data calibrated using The Geologic Time Scale 201251 (Extended Data Fig. 2). Diatom and radiolarian biostratigraphic data were compiled from a variety of published sources52,53. The magnetic stratigraphy of ODP Site 744 was compiled from refs. 19,54.

Fossil fish debris sample preparation for neodymium isotope analyses

Fish teeth and bones (fish debris) were handpicked from the >63 μm sediment fractions isolated by wet sieving. A total of 31 samples from Site 278 and 91 samples from Site 744 were selected for fish debris Nd isotope analyses. All samples were treated with ultraclean 18 MΩ water and methanol following ref. 55 to remove debris from surfaces and cavities (see also ref. 56). Cleaned fish debris samples were subsequently transferred into pre-cleaned microcentrifuge tubes and dissolved overnight in 50 μl of 2 M HCl. Dissolved fish debris samples were loaded on Biorad cation exchange resin (200–400 μm mesh) to separate the rare earth elements (REEs) from the sample matrix and Eichrom Ln-Spec resin (50–100 μm bead size) to separate Nd from the other REEs. In addition, 49 dissolved fish debris samples from ODP Site 744 (early to late Miocene) were cleaned with the same methodology. Cleaned fish debris samples were subsequently transferred into pre-cleaned microcentrifuge tubes and dissolved overnight in 50 μl of 3 M HNO3. Dissolved fish debris samples were loaded on Tru-spec resin to separate the REEs from the sample matrix and Ln-Spec resin chromatography to separate Nd from the other REEs.

Bulk sediment sample preparation for neodymium isotope analyses

Two samples from Site 278 were selected to determine the detrital sediment Nd isotope composition to evaluate the potential contribution of the detrital sediments to the porewaters and/or overlying bottom-water signatures. Samples were dried and gently homogenized using mortar and pestle. First, 1.5 g dried sample and 70–75 ml 1.5% buffered acetic acid solution were used to remove biogenic carbonate (carbonate leaching). Exchangeable ions were subsequently removed using 10 ml 1 M MgCl2 solution. In a third step, ferromanganese oxides and oxyhydroxides were removed using leaching in a weak reductive solution of 0.005 M hydroxylamine hydrochloride (NH2OH), 1.5% acetic acid and 0.03 M Na2–EDTA for 1 h, followed by a stronger leaching step utilizing 0.05 M NH2OH for 17 h. Subsequently, 50 mg of leached and water washed detrital sediment was digested on a hotplate using a mixture of 1 ml concentrated HNO3, 0.8 ml HClO4 and 2 ml HF. The detrital samples were processed using the same column chromatography as the fish debris from Site 278.

Neodymium isotope measurements

Neodymium isotope ratios for fish debris and detrital sediment samples from Site 278 were determined on a Nu Plasma multicollector inductively coupled plasma mass spectrometer (MC-ICP-MS) at Imperial College London, operated in static mode. Instrumental mass bias was corrected using the 146Nd/144Nd ratio of 0.7219. A JNdi-1 isotope standard was run after every sample, and all reported 143Nd/144Nd ratios were corrected to a JNdi 143Nd/144Nd ratio of 0.512115 (ref. 57) using bracketing standards. External reproducibility was monitored using JNdi standards, and accuracy was confirmed by measuring USGS BCR-2 rock standards with each batch of samples, yielding average 143Nd/144Nd ratios of 0.512636 ± 0.000010 (n = 17; 2 s.d.) in excellent agreement with the published BCR-2 143Nd/144Nd ratio of 0.512638 ± 0.000015 (ref. 58).

Neodymium isotope ratios for 42 fish debris samples from Site 744 were determined using a Thermo Scientific Triton Plus thermal ionization mass spectrometer at the Observatoire Midi-Pyrenees. Samples were dissolved in 200 μl of 0.05 M HNO3 and loaded on degassed rhenium filaments. Measured 143Nd/144Nd ratios are an average of 150 measurements of ion intensities following the static multi-collection mode. Instrumental mass bias was corrected using the 146Nd/144Nd ratio of 0.7219. During the whole measurement period, 13 Rennes standards were measured repetitively to determine the internal reproducibility. The Rennes measurements gave a mean 143Nd/144Nd isotope ratio of 0.511953 ± 0.00004 (2 s.d., n = 13), in agreement with published Rennes 143Nd/144Nd ratio of 0.511961 ± 0.000013 ref. 59).

Neodymium isotope ratios for 49 fish debris samples from Site 744 were performed using a Plasma 3 MC-ICP-MS (Nu Instruments–AMETEK) at Centres Cientifics I Tecnologics of the Universitat de Barcelona. The 143Nd/144Nd instrumental mass bias was corrected using the reference 146Nd/144Nd ratio of 0.7219. Moreover, a JNdi-1 standard was analysed before and after each sample, and an additional sample-standard bracketing normalization of the mass bias-corrected ratios was carried out using the reference 143Nd/144Nd value of 0.512115 ± 0.000007 for this standard57. Uncertainties of the εNd values correspond to the external reproducibility of the JNdi-1 analysis performed throughout each measurement session (2 s.d., n = 22–34). Uncertainties were 0.14 to 0.21 εNd units. The accuracy of the method has been demonstrated through multiple analyses of the AMES II standard (0.511973 + / − 0.000012, 2 s.d. = 24 ppm, n = 116), and results were not significantly different from those previously published24. Procedural blanks were systematically negligible with the three methods.

REE concentrations

The REE concentration measurements from 39 fish debris samples at Site 744 were made on aliquots of the same samples used for Nd isotope analysis, using a Thermo Scientific Element XR high-resolution ICP-MS at the Observatoire Midi-Pyrenees. Indium and Rhenium were used as internal standards during ICP-MS measurements to monitor instrumental drift during the course of the analyses. The instrument was calibrated using a synthetic multi-element solution routinely used by the Observatoire Midi-Pyrenees ICP-MS service. This calibration solution has been analysed with three different dilution factors, at the beginning and at the end of the analyses, to calibrate the instrument response and correct the drift along the analytical sequence. Oxide interferences (BaO+ on Nd+ and Eu+, light REE on intermediate REE and intermediate REE on heavy REE) were then corrected. However, these interferences were very low since the samples were injected via an ARIDUS II desolvating nebulizer system. The precision and accuracy of ICP-MS analyses were assessed by measuring the natural river water reference materials SLRS 6. All REE data were normalized to post-Archaean shale concentrations60.

To correct for the in situ decay of 147Sm to 144Nd within the fish debris at Site 278 over time, we used a site-specific average 147Sm/144Nd ratio of 0.1365, based on samples of fish debris measured from older parts at the same site10. For Site 744, we used the147Sm/144Nd ratio for sample that we measured Sm and Nd concentrations and a site-specific average 147Sm/144Nd ratio of 0.1333 based on samples of fish debris measured from older parts at the same site20. Corrections for the in situ decay of 147Sm to 144Nd amounted to 0.01–0.16 εNd units for both sites. Decay-corrected ratios are denoted with (t) in all figures and text.

Grain-size analyses

Grain-size analyses were performed at the Environnements et Paléoenvironnements Océaniques et Continentaux (University of Bordeaux). Bulk grain size was measured in a total of 44 samples from Site 278: 28 samples from cores 2R–25R and 16 samples from cores 26R–34R using a laser microgranulometer Malvern mastersizer hydro 2000G with automatic samples (0.020 to 2,000 μm). To separate the terrigenous sediment fraction, we used 1–2 ml HCl 37% (hydrochloric acid) to dissolve carbonate and 20 ml H2O2 (hydrogen peroxide) to remove organic carbon. Moreover, to remove the biogenic (opaline) silica, samples were separated into two groups: (1) sediments with low silica content and (2) sediments with high silica content. For the first group, 40 ml Na2CO3 (2 M) (sodium carbonate) was used, while 20 ml NaOH (1 M) (sodium hydroxide) was used for sediments with high silica content. Smear slides were prepared to verify efficient removal of siliceous microfossils under a microscope at ×500 magnification.

To reconstruct the current speed, we focused on the 10–63 μm terrigenous sediment fraction—the sortable silt range (SS)22. Particles smaller than 10 μm are deposited as aggregates due to cohesion and thus cannot be used as a proxy for current velocity, whereas the sediment fraction between 10 and 63 μm has been documented to reflect current sorting in most cases22. The mean sortable silt size of the 10–63 μm terrigenous sediment fraction (\(\overline{{\rm{SS}}}\)) was calculated in all 44 samples at Site 278 after the removal of carbonates, organic matter and biogenic silica. Precision of the method was ±3%.

Model simulations

To understand the role of the tectonic opening of the 53.5° S passage within the Macquarie Ridge complex on local ocean circulation and ACC strengthening, we ran two model simulations, with the only change being the ridge bathymetry, using the primitive equation Massachusetts Institute of Technology general circulation model61. The model simulations were limited to a regional domain, extending from 145 to 175° E and 48 to 60° S. We used open boundary conditions with steady-state, annual mean temperature, salinity and velocity fields from the Southern Ocean State Estimate62. The circulation was restored to these boundary conditions along a 1° wide sponge along all lateral boundaries. Sea surface temperatures and salinities were restored to steady annual mean fields with a restoring timescale of ten days. The wind stress was also a steady mean field from Southern Ocean State Estimate. The model configurations used a free surface, free-slip boundary conditions, a quadratic bottom drag with a coefficient of 0.002 and a nonlinear equation of state63.

The model configurations used a horizontal resolution of 1/20° and 200 vertical levels ranging from 4 m at the surface to 40 m at depth. The maximum ocean depth is 6,000 m. The modern-day bathymetry was taken from the Shuttle Radar Topography Mission, SRTM30_PLUS64,65. The model configuration with the ‘open’ passage was the same as used by ref. 66. To test how much the 53.5° S passage hampers the ACC flow across the ridge, we ran a second model where the bathymetry was modified, adjusting the depth of the 53.5° S passage to 500 m to be aligned with the surrounding ridge depth (‘closed ridge’ configuration). The model was run for 20 years, with the figures showing output averaged over the last 10 years.