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1. Late Miocene to Early Pliocene paleoceanographic evolution of the Central South Pacific: A deep-sea benthic foraminiferal perspective

Author

Das, S, Mahanta, N, Sahoo, B, Singh, R, Alvarez Zarikian, C, Tiwari, M, Vats, N, Nihal, Lamy, F, Winckler, G, Middleton, J, Arz, H, Gottschalk, J, Basak, C, Brombacher, A, Esper, O, Farmer, J, Herbert, L, Iwasaki, S, Lembke-Jene, L, Lawson, V, Lo, L, Malinverno, E, Michel, E, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Seo, I, Smith, R, Souza, A, Stoner, J, de Oliveira, I, Wan, S, Zhao, X, Das S. K., Mahanta N., Sahoo B., Singh R. K., Alvarez Zarikian C. A., Tiwari M., Vats N., Lamy F., Winckler G., Middleton J. L., Arz H. W., Gottschalk J., Basak C., Brombacher A., Esper O. M., Farmer J. R., Herbert L. C., Iwasaki S., Lembke-Jene L., Lawson V. J., Lo L., Malinverno E., Michel E., Moretti S., Moy C. M., Ravelo A. C., Riesselman C. R., Saavedra-Pellitero M., Seo I., Smith R. A., Souza A. L., Stoner J. S., de Oliveira I. V. M. P., Wan S., Zhao X., Das, S, Mahanta, N, Sahoo, B, Singh, R, Alvarez Zarikian, C, Tiwari, M, Vats, N, Nihal, Lamy, F, Winckler, G, Middleton, J, Arz, H, Gottschalk, J, Basak, C, Brombacher, A, Esper, O, Farmer, J, Herbert, L, Iwasaki, S, Lembke-Jene, L, Lawson, V, Lo, L, Malinverno, E, Michel, E, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Seo, I, Smith, R, Souza, A, Stoner, J, de Oliveira, I, Wan, S, Zhao, X, Das S. K., Mahanta N., Sahoo B., Singh R. K., Alvarez Zarikian C. A., Tiwari M., Vats N., Lamy F., Winckler G., Middleton J. L., Arz H. W., Gottschalk J., Basak C., Brombacher A., Esper O. M., Farmer J. R., Herbert L. C., Iwasaki S., Lembke-Jene L., Lawson V. J., Lo L., Malinverno E., Michel E., Moretti S., Moy C. M., Ravelo A. C., Riesselman C. R., Saavedra-Pellitero M., Seo I., Smith R. A., Souza A. L., Stoner J. S., de Oliveira I. V. M. P., Wan S., and Zhao X.

Abstract

The bottom water conditions in the Central South Pacific (CSP) and associated changes in the Lower Circumpolar Deep Water (LCDW) and Antarctic Bottom Water (AABW) under warmer-than-present conditions need to be better understood. These water masses transfer their properties to the major ocean basins. We analyzed Late Miocene to Early Pliocene (5.6–3.6 Ma) marine sediment core sections from the CSP for benthic foraminifera, ice rafted debris (IRD), Ostracoda, planktic foraminifera Orbulina universa abundance, and organic geochemical proxies to assess the bottom water characteristics under warmer-than-present day conditions. A significant increase in IRD abundance between 5.3 and 4.9 Ma marks the Early Pliocene warm phase. The benthic foraminiferal assemblages indicate shifts in bottom water conditions over time in the CSP region. Between 5.6 and 5.3 Ma, predominantly oxygenated bottom water with moderate organic matter flux prevailed. This shifted to suboxic conditions with increased organic matter flux from 5.3 to 4.9 Ma. Subsequently, between 4.9 and 4.4 Ma, bottom water conditions alternated frequently between oxic and suboxic states. Enhanced bottom water formation and inflow of LCDW and AABW in the CSP during 4.4–4.0 Ma promoted oxygenated conditions, accompanied by low organic export flux. However, sluggish bottom water circulation from 4.0 to 3.6 Ma reverted to suboxic conditions, associated with increased carbon burial. Notably, productivity peaked intermittently between 5.3 and 3.6 Ma, as indicated by the occurrence of suboxic species assemblages and increase in the abundance of Orbulina universa, benthic microfauna (ostracods), and other paleoproductivity indicators.

Published
2024

2. Five million years of Antarctic Circumpolar Current strength variability

Author

Lamy, F, Winckler, G, Arz, H, Farmer, J, Gottschalk, J, Lembke-Jene, L, Middleton, J, van der Does, M, Tiedemann, R, Alvarez Zarikian, C, Basak, C, Brombacher, A, Dumm, L, Esper, O, Herbert, L, Iwasaki, S, Kreps, G, Lawson, V, Lo, L, Malinverno, E, Martinez-Garcia, A, Michel, E, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Sadatzki, H, Seo, I, Singh, R, Smith, R, Souza, A, Stoner, J, Toyos, M, de Oliveira, I, Wan, S, Wu, S, Zhao, X, Lamy F., Winckler G., Arz H. W., Farmer J. R., Gottschalk J., Lembke-Jene L., Middleton J. L., van der Does M., Tiedemann R., Alvarez Zarikian C., Basak C., Brombacher A., Dumm L., Esper O. M., Herbert L. C., Iwasaki S., Kreps G., Lawson V. J., Lo L., Malinverno E., Martinez-Garcia A., Michel E., Moretti S., Moy C. M., Ravelo A. C., Riesselman C. R., Saavedra-Pellitero M., Sadatzki H., Seo I., Singh R. K., Smith R. A., Souza A. L., Stoner J. S., Toyos M., de Oliveira I. M. V. P., Wan S., Wu S., Zhao X., Lamy, F, Winckler, G, Arz, H, Farmer, J, Gottschalk, J, Lembke-Jene, L, Middleton, J, van der Does, M, Tiedemann, R, Alvarez Zarikian, C, Basak, C, Brombacher, A, Dumm, L, Esper, O, Herbert, L, Iwasaki, S, Kreps, G, Lawson, V, Lo, L, Malinverno, E, Martinez-Garcia, A, Michel, E, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Sadatzki, H, Seo, I, Singh, R, Smith, R, Souza, A, Stoner, J, Toyos, M, de Oliveira, I, Wan, S, Wu, S, Zhao, X, Lamy F., Winckler G., Arz H. W., Farmer J. R., Gottschalk J., Lembke-Jene L., Middleton J. L., van der Does M., Tiedemann R., Alvarez Zarikian C., Basak C., Brombacher A., Dumm L., Esper O. M., Herbert L. C., Iwasaki S., Kreps G., Lawson V. J., Lo L., Malinverno E., Martinez-Garcia A., Michel E., Moretti S., Moy C. M., Ravelo A. C., Riesselman C. R., Saavedra-Pellitero M., Sadatzki H., Seo I., Singh R. K., Smith R. A., Souza A. L., Stoner J. S., Toyos M., de Oliveira I. M. V. P., Wan S., Wu S., and Zhao X.

Abstract

The Antarctic Circumpolar Current (ACC) represents the world’s largest ocean-current system and affects global ocean circulation, climate and Antarctic ice-sheet stability1–3. Today, ACC dynamics are controlled by atmospheric forcing, oceanic density gradients and eddy activity4. Whereas palaeoceanographic reconstructions exhibit regional heterogeneity in ACC position and strength over Pleistocene glacial–interglacial cycles5–8, the long-term evolution of the ACC is poorly known. Here we document changes in ACC strength from sediment cores in the Pacific Southern Ocean. We find no linear long-term trend in ACC flow since 5.3 million years ago (Ma), in contrast to global cooling9 and increasing global ice volume10. Instead, we observe a reversal on a million-year timescale, from increasing ACC strength during Pliocene global cooling to a subsequent decrease with further Early Pleistocene cooling. This shift in the ACC regime coincided with a Southern Ocean reconfiguration that altered the sensitivity of the ACC to atmospheric and oceanic forcings11–13. We find ACC strength changes to be closely linked to 400,000-year eccentricity cycles, probably originating from modulation of precessional changes in the South Pacific jet stream linked to tropical Pacific temperature variability14. A persistent link between weaker ACC flow, equatorward-shifted opal deposition and reduced atmospheric CO2 during glacial periods first emerged during the Mid-Pleistocene Transition (MPT). The strongest ACC flow occurred during warmer-than-present intervals of the Plio-Pleistocene, providing evidence of potentially increasing ACC flow with future climate warming.

Published
2024

3. Site U1542

Author

Lamy, F., primary, Winckler, G., additional, Alvarez Zarikian, C.A., additional, Arz, H.W., additional, Basak, C., additional, Brombacher, A., additional, Esper, O.M., additional, Farmer, J.R., additional, Gottschalk, J., additional, Herbert, L.C., additional, Iwasaki, S., additional, Lawson, V.J., additional, Lembke-Jene, L., additional, Lo, L., additional, Malinverno, E., additional, Michel, E., additional, Middleton, J.L., additional, Moretti, S., additional, Moy, C.M., additional, Ravelo, A.C., additional, Riesselman, C.R., additional, Saavedra-Pellitero, M., additional, Seo, I., additional, Singh, R.K., additional, Smith, R.A., additional, Souza, A.L., additional, Stoner, J.S., additional, Venancio, I.M., additional, Wan, S., additional, Zhao, X., additional, and Foucher McColl, N., additional

Published
2021
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4. Site U1539

Author

Winckler, G., primary, Lamy, F., additional, Alvarez Zarikian, C.A., additional, Arz, H.W., additional, Basak, C., additional, Brombacher, A., additional, Esper, O.M., additional, Farmer, J.R., additional, Gottschalk, J., additional, Herbert, L.C., additional, Iwasaki, S., additional, Lawson, V.J., additional, Lembke-Jene, L., additional, Lo, L., additional, Malinverno, E., additional, Michel, E., additional, Middleton, J.L., additional, Moretti, S., additional, Moy, C.M., additional, Ravelo, A.C., additional, Riesselman, C.R., additional, Saavedra-Pellitero, M., additional, Seo, I., additional, Singh, R.K., additional, Smith, R.A., additional, Souza, A.L., additional, Stoner, J.S., additional, Venancio, I.M., additional, Wan, S., additional, Zhao, X., additional, and Foucher McColl, N., additional

Published
2021
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5. Expedition 383 methods

Author

Winckler, G., primary, Lamy, F., additional, Alvarez Zarikian, C.A., additional, Arz, H.W., additional, Basak, C., additional, Brombacher, A., additional, Esper, O.M., additional, Farmer, J.R., additional, Gottschalk, J., additional, Herbert, L.C., additional, Iwasaki, S., additional, Lawson, V.J., additional, Lembke-Jene, L., additional, Lo, L., additional, Malinverno, E., additional, Michel, E., additional, Middleton, J.L., additional, Moretti, S., additional, Moy, C.M., additional, Ravelo, A.C., additional, Riesselman, C.R., additional, Saavedra-Pellitero, M., additional, Seo, I., additional, Singh, R.K., additional, Smith, R.A., additional, Souza, A.L., additional, Stoner, J.S., additional, Venancio, I.M., additional, Wan, S., additional, Zhao, X., additional, and Foucher McColl, N., additional

Published
2021
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6. Expedition 383 summary

Author

Winckler, G., primary, Lamy, F., additional, Alvarez Zarikian, C.A., additional, Arz, H.W., additional, Basak, C., additional, Brombacher, A., additional, Esper, O.M., additional, Farmer, J.R., additional, Gottschalk, J., additional, Herbert, L.C., additional, Iwasaki, S., additional, Lawson, V.J., additional, Lembke-Jene, L., additional, Lo, L., additional, Malinverno, E., additional, Michel, E., additional, Middleton, J.L., additional, Moretti, S., additional, Moy, C.M., additional, Ravelo, A.C., additional, Riesselman, C.R., additional, Saavedra-Pellitero, M., additional, Seo, I., additional, Singh, R.K., additional, Smith, R.A., additional, Souza, A.L., additional, Stoner, J.S., additional, Venancio, I.M., additional, Wan, S., additional, Zhao, X., additional, and Foucher McColl, N., additional

Published
2021
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9. Expedition 383 summary

Author

Lamy, F., Winckler, G., Alvarez Zarikian, C.A., and the Expedition 383 Scientists, Winckler, G, Lamy, F, Alvarez Zarikian, C, Arz, H, Basak, C, Brombacher, A, Esper, O, Farmer, J, Gottschalk, J, Herbert, L, Iwasaki, S, Lawson, V, Lembke-Jene, L, Lo, L, Malinverno, E, Michel, E, Middleton, J, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Seo, I, Singh, R, Smith, R, Souza, A, Stoner, J, Venancio, I, Wan, S, Zhao, X, Foucher McColl, N, Winckler, G., Lamy, F., Alvarez Zarikian, C. A., Arz, H. W., Basak, C., Brombacher, A., Esper, O. M., Farmer, J. R., Gottschalk, J., Herbert, L. C., Iwasaki, S., Lawson, V. J., Lembke-Jene, L., Lo, L., Malinverno, E., Michel, E., Middleton, J. L., Moretti, S., Moy, C. M., Ravelo, A. C., Riesselman, C. R., Saavedra-Pellitero, M., Seo, I., Singh, R. K., Smith, R. A., Souza, A. L., Stoner, J. S., Venancio, I. M., Wan, S., Zhao, X., Foucher McColl, N., Lamy, F., Winckler, G., Alvarez Zarikian, C.A., and the Expedition 383 Scientists, Winckler, G, Lamy, F, Alvarez Zarikian, C, Arz, H, Basak, C, Brombacher, A, Esper, O, Farmer, J, Gottschalk, J, Herbert, L, Iwasaki, S, Lawson, V, Lembke-Jene, L, Lo, L, Malinverno, E, Michel, E, Middleton, J, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Seo, I, Singh, R, Smith, R, Souza, A, Stoner, J, Venancio, I, Wan, S, Zhao, X, Foucher McColl, N, Winckler, G., Lamy, F., Alvarez Zarikian, C. A., Arz, H. W., Basak, C., Brombacher, A., Esper, O. M., Farmer, J. R., Gottschalk, J., Herbert, L. C., Iwasaki, S., Lawson, V. J., Lembke-Jene, L., Lo, L., Malinverno, E., Michel, E., Middleton, J. L., Moretti, S., Moy, C. M., Ravelo, A. C., Riesselman, C. R., Saavedra-Pellitero, M., Seo, I., Singh, R. K., Smith, R. A., Souza, A. L., Stoner, J. S., Venancio, I. M., Wan, S., Zhao, X., and Foucher McColl, N.

Abstract

The Antarctic Circumpolar Current (ACC), the world’s strongest zonal current system, connects all three major ocean basins of the global ocean and therefore integrates and responds to global climate variability. Its flow is largely driven by strong westerly winds and is constricted to its narrowest extent in the Drake Passage. Fresh and cold Pacific surface and intermediate water flowing through the Drake Passage (cold-water route) and warm Indian Ocean water masses flowing through the Agulhas region (warm-water route) are critical for the South Atlantic contribution to Meridional Overturning Circulation changes. Furthermore, physical and biological processes associated with the ACC affect the strength of the ocean carbon pump and therefore are critical to feedbacks linking atmospheric CO2 concentrations, ocean circulation, and climate/cryosphere on a global scale. In contrast to the Atlantic and Indian sectors of the ACC, and with the exception of drill cores from the Antarctic continental margin and off New Zealand, there are no deep-sea drilling paleoceanographic records from the Pacific sector of the ACC. To advance our understanding of Miocene to Holocene atmosphere-ocean-cryosphere dynamics in the Pacific and their implications for regional and global climate and atmospheric CO2, International Ocean Discovery Program Expedition 383 recovered sedimentary sequences at (1) three sites in the central South Pacific (CSP) (U1539, U1540, and U1541), (2) two sites at the Chilean margin (U1542 and U1544), and (3) one site from the pelagic eastern South Pacific (U1543) close to the entrance to the Drake Passage. Because of persistently stormy conditions and the resulting bad weather avoidance, we were not successful in recovering the originally planned Proposed Site CSP-3A in the Polar Frontal Zone of the CSP. The drilled sediments at Sites U1541 and U1543 reach back to the late Miocene, and those at Site U1540 reach back to the early Pliocene. High sedimentation rate s

Published
2021

13. International Ocean Discovery Program. Expedition 383 Preliminary Report. Dynamics of the Pacific Antarctic Circumpolar Current (DYNAPACC). 20 May–20 July 2019

Author

Lamy, F, Winckler, G, Alvarez Zarikian, C, Arz, H, Basak, C, Brombacher, A, Esper, O, Farmer, J, Gottschalk, J, Herbert, L, Iwasaki, S, Lawson, V, Lembke-Jene, L, Lo, L, de Souza, A, Malinverno, E, Michel, E, Middleton, J, Moretti, S, Moy, C, Ravelo, C, Riesselman, C, Pellitero, M, Mccoll, N, Proctor, S, Seo, I, Singh, R, Smith, R, Stoner, J, Venancio P de Oliveira, I, Wan, S, Zhao, X, Cimagala, B, Wilkins, A, Lamy, F, Winckler, G, Alvarez Zarikian, C, Arz, H, Basak, C, Brombacher, A, Esper, O, Farmer, J, Gottschalk, J, Herbert, L, Iwasaki, S, Lawson, V, Lembke-Jene, L, Lo, L, de Souza, A, Malinverno, E, Michel, E, Middleton, J, Moretti, S, Moy, C, Ravelo, C, Riesselman, C, Pellitero, M, Mccoll, N, Proctor, S, Seo, I, Singh, R, Smith, R, Stoner, J, Venancio P de Oliveira, I, Wan, S, Zhao, X, Cimagala, B, and Wilkins, A

Subjects
Antarctic Circumpolar Current, Paleoclimate
Abstract

The Antarctic Circumpolar Current (ACC) is the world’s strongest zonal current system that connects all three major ocean basins of the global ocean and therefore integrates and responds to global climate variability. Its flow is largely driven by strong westerly winds and constricted to its narrowest extent in the Drake Passage. Transport of fresh and cold surface and intermediate water masses through the Drake Passage (cold-water route) strongly affects the Atlantic Meridional Overturning Circulation together with the inflow of Indian Ocean water masses (warm-water route). Both oceanographic corridors are critical for the South Atlantic contribution to Meridional Overturning Circulation changes. In contrast to the Atlantic and Indian sectors of the ACC, and with the exception of drill cores from the Antarctic continental margin and off New Zealand, the Pacific sector of the ACC lacks information on its Cenozoic paleoceanography from deep-sea drilling records. To advance our knowledge and understanding of Miocene to Holocene atmosphere-ocean-cryosphere dynamics in the Pacific and their implications for regional and global climate and atmospheric CO2, International Ocean Discovery Program (IODP) Expedition 383 recovered sedimentary sequences at (1) three sites located in the central South Pacific (U1539, U1540, and U1541), (2) two sites at the Chile margin (U1542 and U1544), and (3) one site from the pelagic eastern South Pacific (U1543) close to the entrance to the Drake Passage. Because of persistently stormy conditions and the resulting bad weather avoidance, we were not successful in recovering the originally planned Proposed Site CSP-3A in the central South Pacific in the Polar Frontal Zone. The drilled sediments at Sites U1541 and U1543 reach back to the late Miocene, and those at Site U1540 reach back to the early Pliocene. High sedimentary rate Pleistocene sedimentary sequences were drilled both in the central South Pacific (Site U1539) and along the Chile margin. Taken together, the sites represent a depth transect from ~1100 m at the Chile margin site (U1542) to ~4070 m in the central South Pacific (Site U1539) and allow investigation of changes in the vertical structure of the ACC, a key issue for understanding the role of the Southern Ocean in the global carbon cycle. The sites are located at latitudes and water depths where sediments will allow the application of a wide range of siliciclastic-, carbonate-, and opal-based proxies to address our objectives of reconstructing with unprecedented stratigraphic detail surface to deep-ocean variations and their relation to atmosphere and cryosphere changes through stadial to interstadial, glacial to interglacial, and warmer than present time intervals.

Published
2019

15. Precession modulation of the South Pacific westerly wind belt over the past million years

Author

Lamy, F., Chiang, J.C.H., Martínez-Méndez, G., Thierens, M., Arz, H.W., Bosmans, J., Hebbeln, D., Lambert, F., Lembke-Jene, L., Stuut, J.-B.W., Lamy, F., Chiang, J.C.H., Martínez-Méndez, G., Thierens, M., Arz, H.W., Bosmans, J., Hebbeln, D., Lambert, F., Lembke-Jene, L., and Stuut, J.-B.W.

Abstract

The southern westerly wind belt (SWW) interacts with the Antarctic Circumpolar Current and strongly impacts the Southern Ocean carbon budget, and Antarctic ice-sheet dynamics across glacial–interglacial cycles. We investigated precipitation-driven sediment input changes to the Southeast Pacific off the southern margin of the Atacama Desert over the past one million years, revealing strong precession (19/23-ka) cycles. Our simulations with 2 ocean–atmosphere general circulation models suggest that observed cyclic rainfall changes are linked to meridional shifts in water vapor transport from the tropical Pacific toward the southern Atacama Desert. These changes reflect a precessional modulation of the split in the austral winter South Pacific jet stream. For precession maxima, we infer significantly enhanced rainfall in the southern Atacama Desert due to a stronger South Pacific split jet with enhanced subtropical/subpolar jets, and a weaker midlatitude jet. Conversely, we derive dry conditions in northern Chile related to reduced subtropical/subpolar jets and an enhanced midlatitude jet for precession minima. The presence of precessional cycles in the Pacific SWW, and lack thereof in other basins, indicate that orbital-scale changes of the SWW were not zonally homogeneous across the Southern Hemisphere, in contrast to the hemispherewide shifts of the SWW suggested for glacial terminations. The strengthening of the jet is unique to the South Pacific realm and might have affected winter-controlled changes in the mixed layer depth, the formation of intermediate water, and the buildup of sea-ice around Antarctica, with implications for the global overturning circulation and the oceanic storage of atmospheric CO2.

Published
2019

16. Surface sediment characteristics related to provenance and ocean circulation in the Drake Passage sector of the Southern Ocean

Author

Wu, S., Kuhn, G., Diekmann, B., Lembke-Jene, L., Tiedemann, R., Zheng, X., Ehrhardt, Sophie, Arz, H.W., Lamy, F., Wu, S., Kuhn, G., Diekmann, B., Lembke-Jene, L., Tiedemann, R., Zheng, X., Ehrhardt, Sophie, Arz, H.W., and Lamy, F.

Abstract

Understanding present-day sediment provenance and transport processes is crucial for studies about the dynamics of ocean circulation, as well as for paleoclimate reconstructions in the Drake Passage (DP), a key area for Earth's global oceanic circulation and climate during past and future. Based on a comprehensive set of surface sediment samples, we used spatial variations in grain-size distribution, bulk sediment mineralogy, silt and clay mineralogy across the entire DP region to elucidate the terrigenous sources and transport mechanisms. The statistical evaluation of these data identifies southern Patagonia (carbonate, illite, chlorite, feldspar and quartz) and the Antarctic Peninsula (chlorite, smectite, and amphibole) as the main sources for terrigenous sediments in the DP region. Different current systems are transporting the sediment material. Here, we provide a new, robust flow speed calibration for silt grain-sizes to enable the reconstruction of Antarctic Circumpolar Current (ACC) dynamics in the DP sector of the Southern Ocean. We correlated the sortable silt mean grain-size records of surface sediments with adjacent long-term current meter data. A clear bottom current speed pattern shows the variability of the ACC in the DP responding to the dynamics of ocean fronts, in agreement with modern observation.

Published
2019

17. Evidence for enhanced convection of North Pacific Intermediate Water to the low-latitude Pacific under glacial conditions

Author

Max, L., Rippert, N., Lembke-jene, L., Mackensen, A., Nürnberg, D., and Tiedemann, R.

Abstract

We provide high-resolution foraminiferal stable carbon isotope (delta C-13) records from the subarctic Pacific and Eastern Equatorial Pacific (EEP) to investigate circulation dynamics between the extratropical and tropical North Pacific during the past 60 kyr. We measured the delta C-13 composition of the epibenthic foraminiferal species Cibicides lobatulus from a shallow sediment core recovered from the western Bering Sea (SO201-2-101KL; 58 degrees 52.52' N, 170 degrees 41.45' E; 630 m water depth) to reconstruct past ventilation changes close to the source region of Glacial North Pacific Intermediate Water (GNPIW). Information regarding glacial changes in the delta C-13 of subthermocline water masses in the EEP is derived from the deep-dwelling planktonic foraminifera Globorotaloides hexagonus at ODP Site 1240 (00 degrees 01.31' N, 82 degrees 27.76' W; 2921m water depth). Apparent similarities in the long-term evolution of delta C-13 between GNPIW, intermediate waters in the eastern tropical North Pacific and subthermocline water masses in the EEP suggest the expansion of relatively delta C-13-depleted, nutrient-enriched, and northern sourced intermediate waters to the equatorial Pacific under glacial conditions. Further, it appears that additional influence of GNPIW to the tropical Pacific is consistent with changes in nutrient distribution and biological productivity in surface waters of the glacial EEP. Our findings highlight potential links between North Pacific mid-depth circulation changes, nutrient cycling, and biological productivity in the equatorial Pacific under glacial boundary conditions.

Published
2017

21. Pulses of enhanced North Pacific Intermediate Water ventilation from the Okhotsk Sea and Bering Sea during the last deglaciation

Author

Max, L., Lembke-Jene, L., Riethdorf, J.-R., Tiedemann, R., Nürnberg, D., Kühn, H., Mackensen, Andreas, Max, L., Lembke-Jene, L., Riethdorf, J.-R., Tiedemann, R., Nürnberg, D., Kühn, H., and Mackensen, Andreas

Abstract

Under modern conditions only North Pacific Intermediate Water is formed in the northwest Pacific Ocean. This situation might have changed in the past. Recent studies with general circulation models indicate a switch to deep-water formation in the northwest Pacific during Heinrich Stadial 1 (17.5–15.0 ka) of the last glacial termination. Reconstructions of past ventilation changes based on paleoceanographic proxy records are still insufficient to test whether a deglacial mode of deep-water formation in the North Pacific Ocean existed. Here we present deglacial ventilation records based on radiocarbon-derived ventilation ages in combination with epibenthic stable carbon isotopes from the northwest Pacific including the Okhotsk Sea and Bering Sea, the two potential source regions for past North Pacific ventilation changes. Evidence for most rigorous ventilation of the intermediate-depth North Pacific occurred during Heinrich Stadial 1 and the Younger Dryas, simultaneous to significant reductions in Atlantic Meridional Overturning Circulation. Concurrent changes in δ13C and ventilation ages point to the Okhotsk Sea as driver of millennial-scale changes in North Pacific Intermediate Water ventilation during the last deglaciation. Our records additionally indicate that changes in the δ13C intermediate-water (700–1750 m water depth) signature and radiocarbon-derived ventilation ages are in antiphase to those of the deep North Pacific Ocean (>2100 m water depth) during the last glacial termination. Thus, intermediate- and deep-water masses of the northwest Pacific have a differing ventilation history during the last deglaciation.

Published
2014

25. Scientific Research in Polar Seas – ERICON Science Perspective 2015-2030

Author

Wilmott, V., Azzolini, R., von Brandt, A., Brinkhuis, H., Camerlenghi, A., Coakley, B., De Santis, L., Kristoffersen, Y., Lembke-Jene, L., Rebesco, M., Thiede, J., and other contributors, ., Wilmott, V., Azzolini, R., von Brandt, A., Brinkhuis, H., Camerlenghi, A., Coakley, B., De Santis, L., Kristoffersen, Y., Lembke-Jene, L., Rebesco, M., Thiede, J., and and other contributors, .

Published
2012

26. 'Aurora Borealis' - novyi evropeiskiy nauchno-issledovateľskiy ledokol v vozmozhnost′yu bureniya ('Aurora Borealis' - a new European research icebreaker with drilling capability, in Russian)

Author

Kassens, Kh., Lisitzin, A. P., Tide, J., Polyakova, Ye. I., Timokhov, L. A., Frolov, I. E., Bibou, N., Lembke-Jene, L., Kunc-Pirrung, M., Kassens, Kh., Lisitzin, A. P., Tide, J., Polyakova, Ye. I., Timokhov, L. A., Frolov, I. E., Bibou, N., Lembke-Jene, L., and Kunc-Pirrung, M.

Published
2009

29. Pulses of enhanced North Pacific Intermediate Water ventilation from the Okhotsk Sea and Bering Sea during the last deglaciation.

Author

Max, L., Lembke-Jene, L., Riethdorf, J.-R., Tiedemann, R., Nürnberg, D., Kühn, H., and Mackensen, A.

Abstract

Under modern conditions only North Pacific Intermediate Water is formed in the Northwest Pacific Ocean. This situation might have changed in the past. Recent studies with General Circulation Models indicate a switch to deep-water formation in the Northwest Pacific during Heinrich Stadial 1 (17.5-15.0 kyr) of the last glacial termination. Reconstructions of past ventilation changes based on paleoceanographic proxy records are still insufficient to test whether a deglacial mode of deep-water formation in the North Pacific Ocean existed. Here we present deglacial ventilation records based on radiocarbon-derived ventilation ages in combination with epibenthic stable carbon isotopes from the Northwest Pacific including the Okhotsk Sea and Bering Sea, the two potential source regions for past North Pacific ventilation changes. Evidence for most rigorous ventilation of the mid-depth North Pacific occurred during Heinrich Stadial 1 and the Younger Dryas, simultaneous to significant reductions in Atlantic Meridional Overturning Circulation. Concurrent changes in δ13C and ventilation ages point to the Okhotsk Sea as driver of millennial-scale changes in North Pacific Intermediate Water ventilation during the last deglaciation. Our records additionally indicate that changes in the δ13C intermediate water (700-1750m water depth) signature and radiocarbonderived ventilation ages are in antiphase to those of the deep North Pacific Ocean (>2100m water depth) during the last glacial termination. Thus, intermediate and deep-water masses of the Northwest Pacific have a differing ventilation history during the last deglaciation. [ABSTRACT FROM AUTHOR]

Published
2013
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30. Proceedings of the International Ocean Discovery Program - Volume 383. Dynamics of the Pacific Antarctic Circumpolar Current

Author

Lamy F., Winckler G., Alvarez Zarikian, C. A. Arz, C. Basak, A. Brombacher, O. M. Esper, J. R. Farmer, J. Gottschalk, L. C. Herbert, S. Iwasaki, V. J. Lawson, L. Lembke-Jene, L. Lo, E. Malinverno, E. Michel, J. L. Middleton, S. Moretti, C. M. Moy, A. C. Ravelo, C. R. Riesselman, M. Saavedra-Pellitero, I. Seo, R. K. Singh, R. A. Smith, A. L. Souza, J. S. Stoner, I. M. Venancio, S. Wan, X. Zhao, and N. Foucher McColl, F., L, G., W, Zarikian, A, Arz, C, Basak, C, Brombacher, A, Esper, O, Farmer, J, Gottschalk, J, Herbert, L, Iwasaki, S, Lawson, V, Lembke-Jene, L, Lo, L, Malinverno, E, Michel, E, Middleton, J, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Seo, I, Singh, R, Smith, R, Souza, A, Stoner, J, Venancio, I, Wan, S, Zhao, X, and Foucher McColl, A

Subjects
Paleoceanography, Antarctic Circumpolar Current, GEO/02 - GEOLOGIA STRATIGRAFICA E SEDIMENTOLOGICA, GEO/01 - PALEONTOLOGIA E PALEOECOLOGIA
Published
2021

31. Expedition 383 summary

Author

Elisa Malinverno, E. Michel, N. Foucher McColl, J. Gottschalk, J.S. Stoner, Mariem Saavedra-Pellitero, V.J. Lawson, L. Lo, S. Moretti, Shiming Wan, Shinya Iwasaki, L.C. Herbert, Gisela Winckler, Igor Martins Venancio, C. A. Alvarez Zarikian, Xiaojian Zhao, Ana Christina Ravelo, C. Basak, Jennifer L. Middleton, Frank Lamy, Christopher M. Moy, A.L. Souza, R.A. Smith, Jesse Farmer, L. Lembke-Jene, Anieke Brombacher, Christina R. Riesselman, Helge W Arz, Oliver Esper, I. Seo, Raj K. Singh, Lamy, F., Winckler, G., Alvarez Zarikian, C.A., and the Expedition 383 Scientists, Winckler, G, Lamy, F, Alvarez Zarikian, C, Arz, H, Basak, C, Brombacher, A, Esper, O, Farmer, J, Gottschalk, J, Herbert, L, Iwasaki, S, Lawson, V, Lembke-Jene, L, Lo, L, Malinverno, E, Michel, E, Middleton, J, Moretti, S, Moy, C, Ravelo, A, Riesselman, C, Saavedra-Pellitero, M, Seo, I, Singh, R, Smith, R, Souza, A, Stoner, J, Venancio, I, Wan, S, Zhao, X, Foucher McColl, N, Lamont-Doherty Earth Observatory (LDEO), Columbia University [New York], Alfred Wegener Institute for Polar and Marine Research (AWI), International Ocean Discovery Program, Leibniz Institute for Baltic Sea Research Warnemünde (IOW), University of Delaware [Newark], National Oceanography Centre (NOC), Department of Geosciences [Princeton], Princeton University, School of Marine and Atmospheric Sciences [Stony Brook] (SoMAS), Stony Brook University [SUNY] (SBU), State University of New York (SUNY)-State University of New York (SUNY), Japan Agency for Marine-Earth Science and Technology (JAMSTEC), Rutgers, The State University of New Jersey [New Brunswick] (RU), Rutgers University System (Rutgers), National Taïwan University (NTU), Università degli Studi di Milano = University of Milan (UNIMI), Laboratoire des Sciences du Climat et de l'Environnement [Gif-sur-Yvette] (LSCE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Paléocéanographie (PALEOCEAN), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Max Planck Institute for Chemistry (MPIC), Max-Planck-Gesellschaft, University of Otago [Dunedin, Nouvelle-Zélande], University of California [Santa Cruz] (UC Santa Cruz), University of California (UC), University of Birmingham [Birmingham], Korea Institute of Ocean Science and Technology (KIOST), Indian Institute of Technology Bhubaneshwar, University of Massachusetts [Amherst] (UMass Amherst), University of Massachusetts System (UMASS), State University of Rio de Janeiro, Oregon State University (OSU), Center for Weather Forecasting and Climate Studies [São Paulo] (CPTEC), Instituto Nacional de Pesquisas Espaciais (INPE), Chinese Academy of Sciences [Beijing] (CAS), National Insitute of Polar Research [Japan], National Institute of Polar Research [Tokyo] (NiPR), and Universidad Andrés Bello [Santiago] (UNAB)

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, International Ocean Discovery Program, GEO/02 - GEOLOGIA STRATIGRAFICA E SEDIMENTOLOGICA, International Ocean Discovery Program, IODP, JOIDES Resolution, Expedition 383, Dynamics of the Pacific Antarctic Circumpolar Current, Site U1539, Site U1540, Site U1541, Site U1542, Site U1543, Site U1544, Southern Ocean, South Pacific, Chilean margin, paleoceanography, Antarctic Circumpolar Current, oceanic fronts, Circumpolar Deep Water, Antarctic Intermediate Water, marine carbon cycle, dust, biological productivity, iron fertilization, southern westerly winds, Patagonian ice sheet, West Antarctic ice sheet, [SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces, environment, GEO/01 - PALEONTOLOGIA E PALEOECOLOGIA, ComputingMilieux_MISCELLANEOUS, Geology, IODP, JOIDES Resolution, Expedition 383
Abstract

The Antarctic Circumpolar Current (ACC), the world’s strongest zonal current system, connects all three major ocean basins of the global ocean and therefore integrates and responds to global climate variability. Its flow is largely driven by strong westerly winds and is constricted to its narrowest extent in the Drake Passage. Fresh and cold Pacific surface and intermediate water flowing through the Drake Passage (cold-water route) and warm Indian Ocean water masses flowing through the Agulhas region (warm-water route) are critical for the South Atlantic contribution to Meridional Overturning Circulation changes. Furthermore, physical and biological processes associated with the ACC affect the strength of the ocean carbon pump and therefore are critical to feedbacks linking atmospheric CO2 concentrations, ocean circulation, and climate/cryosphere on a global scale. In contrast to the Atlantic and Indian sectors of the ACC, and with the exception of drill cores from the Antarctic continental margin and off New Zealand, there are no deep-sea drilling paleoceanographic records from the Pacific sector of the ACC. To advance our understanding of Miocene to Holocene atmosphere-ocean-cryosphere dynamics in the Pacific and their implications for regional and global climate and atmospheric CO2, International Ocean Discovery Program Expedition 383 recovered sedimentary sequences at (1) three sites in the central South Pacific (CSP) (U1539, U1540, and U1541), (2) two sites at the Chilean margin (U1542 and U1544), and (3) one site from the pelagic eastern South Pacific (U1543) close to the entrance to the Drake Passage. Because of persistently stormy conditions and the resulting bad weather avoidance, we were not successful in recovering the originally planned Proposed Site CSP-3A in the Polar Frontal Zone of the CSP. The drilled sediments at Sites U1541 and U1543 reach back to the late Miocene, and those at Site U1540 reach back to the early Pliocene. High sedimentation rate sequences reaching back to the early Pleistocene (Site U1539) and the late Pleistocene (Sites U1542 and U1544) were recovered in both the CSP and at the Chilean margin. Taken together, the sites represent a depth transect from ~1100 m at Chilean margin Site U1542 to ~4070 m at CSP Site U1539 and allow investigation of changes in the vertical structure of the ACC, a key issue for understanding the role of the Southern Ocean in the global carbon cycle. The sites are located at latitudes and water depths where sediments will allow the application of a wide range of siliciclastic-, carbonate-, and opal-based proxies to address our objectives of reconstructing, with unprecedented stratigraphic detail, surface to deep-ocean variations and their relation to atmosphere and cryosphere changes.

Published
2021
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32. A marine record of Patagonian ice sheet changes over the past 140,000 years.

Author

Hagemann JR, Lamy F, Arz HW, Lembke-Jene L, Auderset A, Harada N, Ho SL, Iwasaki S, Kaiser J, Lange CB, Murayama M, Nagashima K, Nowaczyk N, Martínez-García A, and Tiedemann R

Abstract

Terrestrial glacial records from the Patagonian Andes and New Zealand Alps document quasi-synchronous Southern Hemisphere-wide glacier advances during the late Quaternary. However, these records are inherently incomplete. Here, we provide a continuous marine record of western-central Patagonian ice sheet (PIS) extent over a complete glacial-interglacial cycle back into the penultimate glacial (~140 ka). Sediment core MR16-09 PC03, located at 46°S and ~150 km offshore Chile, received high terrestrial sediment and meltwater input when the central PIS extended westward. We use biomarkers, foraminiferal oxygen isotopes, and major elemental data to reconstruct terrestrial sediment and freshwater input related to PIS variations. Our sediment record documents three intervals of general PIS marginal fluctuations, during Marine Isotope Stage (MIS) 6 (140 to 135 ka), MIS 4 (~70 to 60 ka), and late MIS 3 to MIS 2 (~40 to 18 ka). These higher terrigenous input intervals occurred during sea-level low stands, when the western PIS covered most of the Chilean fjords, which today retain glaciofluvial sediments. During these intervals, high-amplitude phases of enhanced sediment supply occur at millennial timescales, reflecting increased ice discharge most likely due to a growing PIS. We assign the late MIS 3 to MIS 2 phases and, by inference, older advances to Antarctic cold stages. We conclude that the increased sediment/meltwater release during Southern Hemisphere millennial-scale cold phases was likely related to higher precipitation caused by enhanced westerly winds at the northwestern margin of the PIS. Our records complement terrestrial archives and provide evidence for PIS climate sensitivity., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published
2024
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33. Five million years of Antarctic Circumpolar Current strength variability.

Author

Lamy F, Winckler G, Arz HW, Farmer JR, Gottschalk J, Lembke-Jene L, Middleton JL, van der Does M, Tiedemann R, Alvarez Zarikian C, Basak C, Brombacher A, Dumm L, Esper OM, Herbert LC, Iwasaki S, Kreps G, Lawson VJ, Lo L, Malinverno E, Martinez-Garcia A, Michel E, Moretti S, Moy CM, Ravelo AC, Riesselman CR, Saavedra-Pellitero M, Sadatzki H, Seo I, Singh RK, Smith RA, Souza AL, Stoner JS, Toyos M, de Oliveira IMVP, Wan S, Wu S, and Zhao X

Abstract

The Antarctic Circumpolar Current (ACC) represents the world's largest ocean-current system and affects global ocean circulation, climate and Antarctic ice-sheet stability 1-3 . Today, ACC dynamics are controlled by atmospheric forcing, oceanic density gradients and eddy activity 4 . Whereas palaeoceanographic reconstructions exhibit regional heterogeneity in ACC position and strength over Pleistocene glacial-interglacial cycles 5-8 , the long-term evolution of the ACC is poorly known. Here we document changes in ACC strength from sediment cores in the Pacific Southern Ocean. We find no linear long-term trend in ACC flow since 5.3 million years ago (Ma), in contrast to global cooling 9 and increasing global ice volume 10 . Instead, we observe a reversal on a million-year timescale, from increasing ACC strength during Pliocene global cooling to a subsequent decrease with further Early Pleistocene cooling. This shift in the ACC regime coincided with a Southern Ocean reconfiguration that altered the sensitivity of the ACC to atmospheric and oceanic forcings 11-13 . We find ACC strength changes to be closely linked to 400,000-year eccentricity cycles, probably originating from modulation of precessional changes in the South Pacific jet stream linked to tropical Pacific temperature variability 14 . A persistent link between weaker ACC flow, equatorward-shifted opal deposition and reduced atmospheric CO 2 during glacial periods first emerged during the Mid-Pleistocene Transition (MPT). The strongest ACC flow occurred during warmer-than-present intervals of the Plio-Pleistocene, providing evidence of potentially increasing ACC flow with future climate warming., (© 2024. The Author(s).)

Published
2024
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34. A global synthesis of high-resolution stable isotope data from benthic foraminifera of the last deglaciation.

Author

Muglia J, Mulitza S, Repschläger J, Schmittner A, Lembke-Jene L, Lisiecki L, Mix A, Saraswat R, Sikes E, Waelbroeck C, Gottschalk J, Lippold J, Lund D, Martinez-Mendez G, Michel E, Muschitiello F, Naik S, Okazaki Y, Stott L, Voelker A, and Zhao N

Subjects
Carbon Isotopes analysis, Carbon, Oxygen, Seawater, Foraminifera
Abstract

We present the first version of the Ocean Circulation and Carbon Cycling (OC3) working group database, of oxygen and carbon stable isotope ratios from benthic foraminifera in deep ocean sediment cores from the Last Glacial Maximum (LGM, 23-19 ky) to the Holocene (<10 ky) with a particular focus on the early last deglaciation (19-15 ky BP). It includes 287 globally distributed coring sites, with metadata, isotopic and chronostratigraphic information, and age models. A quality check was performed for all data and age models, and sites with at least millennial resolution were preferred. Deep water mass structure as well as differences between the early deglaciation and LGM are captured by the data, even though its coverage is still sparse in many regions. We find high correlations among time series calculated with different age models at sites that allow such analysis. The database provides a useful dynamical approach to map physical and biogeochemical changes of the ocean throughout the last deglaciation., (© 2023. The Author(s).)

Published
2023
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35. Quantifying calcium carbonate and organic carbon content in marine sediments from XRF-scanning spectra with a machine learning approach.

Author

Lee AS, Chao WS, Liou SYH, Tiedemann R, Zolitschka B, and Lembke-Jene L

Subjects
X-Rays, Fluorescence, Machine Learning, Geologic Sediments, Calcium Carbonate, Carbon
Abstract

Geochemical variations of sedimentary records contain vital information for understanding paleoenvironment and paleoclimate. However, to obtain quantitative data in the laboratory is laborious, which ultimately restricts the temporal and spatial resolution. Quantification based on fast-acquisition and high-resolution provides a potential solution but is restricted to qualitative X-ray fluorescence (XRF) core scanning data. Here, we apply machine learning (ML) to advance the quantification progress and target calcium carbonate (CaCO 3 ) and total organic carbon (TOC) for quantification to test the potential of such an XRF-ML approach. Raw XRF spectra are used as input data instead of software-based extraction of elemental intensities to avoid bias and increase information. Our dataset comprises Pacific and Southern Ocean marine sediment cores from high- to mid-latitudes to extend the applicability of quantification models from a site-specific to a multi-regional scale. ML-built models are carefully evaluated with a training set, a test set and a case study. The acquired ML-models provide better results with R 2 of 0.96 for CaCO 3 and 0.78 for TOC than conventional methods. In our case study, the ML-performance for TOC is comparably lower but still provides potential for future optimization. Altogether, this study allows to conveniently generate high-resolution bulk chemistry records without losing accuracy., (© 2022. The Author(s).)

Published
2022
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36. Evidence for late-glacial oceanic carbon redistribution and discharge from the Pacific Southern Ocean.

Author

Iwasaki S, Lembke-Jene L, Nagashima K, Arz HW, Harada N, Kimoto K, and Lamy F

Subjects
Ice Cover, Oceans and Seas, Carbon Dioxide analysis, Water, Atmosphere, Seawater
Abstract

Southern Ocean deep-water circulation plays a vital role in the global carbon cycle. On geological time scales, upwelling along the Chilean margin likely contributed to the deglacial atmospheric carbon dioxide rise, but little quantitative evidence exists of carbon storage. Here, we develop an X-ray Micro-Computer-Tomography method to assess foraminiferal test dissolution as proxy for paleo-carbonate ion concentrations ([CO 3 2- ]). Our subantarctic Southeast Pacific sediment core depth transect shows significant deep-water [CO 3 2- ] variations during the Last Glacial Maximum and Deglaciation (10-22 ka BP). We provide evidence for an increase in [CO 3 2- ] during the early-deglacial period (15-19 ka BP) in Lower Circumpolar Deepwater. The export of such low-carbon deep-water from the Pacific to the Atlantic contributed to significantly lowered carbon storage within the Southern Ocean, highlighting the importance of a dynamic Pacific-Southern Ocean deep-water reconfiguration for shaping late-glacial oceanic carbon storage, and subsequent deglacial oceanic-atmospheric CO 2 transfer., (© 2022. The Author(s).)

Published
2022
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38. Orbital- and millennial-scale Antarctic Circumpolar Current variability in Drake Passage over the past 140,000 years.

Author

Wu S, Lembke-Jene L, Lamy F, Arz HW, Nowaczyk N, Xiao W, Zhang X, Hass HC, Titschack J, Zheng X, Liu J, Dumm L, Diekmann B, Nürnberg D, Tiedemann R, and Kuhn G

Abstract

The Antarctic Circumpolar Current (ACC) plays a crucial role in global ocean circulation by fostering deep-water upwelling and formation of new water masses. On geological time-scales, ACC variations are poorly constrained beyond the last glacial. Here, we reconstruct changes in ACC strength in the central Drake Passage in vicinity of the modern Polar Front over a complete glacial-interglacial cycle (i.e., the past 140,000 years), based on sediment grain-size and geochemical characteristics. We found significant glacial-interglacial changes of ACC flow speed, with weakened current strength during glacials and a stronger circulation in interglacials. Superimposed on these orbital-scale changes are high-amplitude millennial-scale fluctuations, with ACC strength maxima correlating with diatom-based Antarctic winter sea-ice minima, particularly during full glacial conditions. We infer that the ACC is closely linked to Southern Hemisphere millennial-scale climate oscillations, amplified through Antarctic sea ice extent changes. These strong ACC variations modulated Pacific-Atlantic water exchange via the "cold water route" and potentially affected the Atlantic Meridional Overturning Circulation and marine carbon storage.

Published
2021
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39. Precession modulation of the South Pacific westerly wind belt over the past million years.

Author

Lamy F, Chiang JCH, Martínez-Méndez G, Thierens M, Arz HW, Bosmans J, Hebbeln D, Lambert F, Lembke-Jene L, and Stuut JB

Abstract

The southern westerly wind belt (SWW) interacts with the Antarctic Circumpolar Current and strongly impacts the Southern Ocean carbon budget, and Antarctic ice-sheet dynamics across glacial-interglacial cycles. We investigated precipitation-driven sediment input changes to the Southeast Pacific off the southern margin of the Atacama Desert over the past one million years, revealing strong precession (19/23-ka) cycles. Our simulations with 2 ocean-atmosphere general circulation models suggest that observed cyclic rainfall changes are linked to meridional shifts in water vapor transport from the tropical Pacific toward the southern Atacama Desert. These changes reflect a precessional modulation of the split in the austral winter South Pacific jet stream. For precession maxima, we infer significantly enhanced rainfall in the southern Atacama Desert due to a stronger South Pacific split jet with enhanced subtropical/subpolar jets, and a weaker midlatitude jet. Conversely, we derive dry conditions in northern Chile related to reduced subtropical/subpolar jets and an enhanced midlatitude jet for precession minima. The presence of precessional cycles in the Pacific SWW, and lack thereof in other basins, indicate that orbital-scale changes of the SWW were not zonally homogeneous across the Southern Hemisphere, in contrast to the hemispherewide shifts of the SWW suggested for glacial terminations. The strengthening of the jet is unique to the South Pacific realm and might have affected winter-controlled changes in the mixed layer depth, the formation of intermediate water, and the buildup of sea-ice around Antarctica, with implications for the global overturning circulation and the oceanic storage of atmospheric CO 2 ., Competing Interests: The authors declare no competing interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published
2019
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40. Deglacial mobilization of pre-aged terrestrial carbon from degrading permafrost.

Author

Winterfeld M, Mollenhauer G, Dummann W, Köhler P, Lembke-Jene L, Meyer VD, Hefter J, McIntyre C, Wacker L, Kokfelt U, and Tiedemann R

Abstract

The mobilization of glacial permafrost carbon during the last glacial-interglacial transition has been suggested by indirect evidence to be an additional and significant source of greenhouse gases to the atmosphere, especially at times of rapid sea-level rise. Here we present the first direct evidence for the release of ancient carbon from degrading permafrost in East Asia during the last 17 kyrs, using biomarkers and radiocarbon dating of terrigenous material found in two sediment cores from the Okhotsk Sea. Upscaling our results to the whole Arctic shelf area, we show by carbon cycle simulations that deglacial permafrost-carbon release through sea-level rise likely contributed significantly to the changes in atmospheric CO 2 around 14.6 and 11.5 kyrs BP.

Published
2018
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41. Rapid shift and millennial-scale variations in Holocene North Pacific Intermediate Water ventilation.

Author

Lembke-Jene L, Tiedemann R, Nürnberg D, Gong X, and Lohmann G

Abstract

The Pacific hosts the largest oxygen minimum zones (OMZs) in the world ocean, which are thought to intensify and expand under future climate change, with significant consequences for marine ecosystems, biogeochemical cycles, and fisheries. At present, no deep ventilation occurs in the North Pacific due to a persistent halocline, but relatively better-oxygenated subsurface North Pacific Intermediate Water (NPIW) mitigates OMZ development in lower latitudes. Over the past decades, instrumental data show decreasing oxygenation in NPIW; however, long-term variations in middepth ventilation are potentially large, obscuring anthropogenic influences against millennial-scale natural background shifts. Here, we use paleoceanographic proxy evidence from the Okhotsk Sea, the foremost North Pacific ventilation region, to show that its modern oxygenated pattern is a relatively recent feature, with little to no ventilation before six thousand years ago, constituting an apparent Early-Middle Holocene (EMH) threshold or "tipping point." Complementary paleomodeling results likewise indicate a warmer, saltier EMH NPIW, different from its modern conditions. During the EMH, the Okhotsk Sea switched from a modern oxygenation source to a sink, through a combination of sea ice loss, higher water temperatures, and remineralization rates, inhibiting ventilation. We estimate a strongly decreased EMH NPIW oxygenation of ∼30 to 50%, and increased middepth Pacific nutrient concentrations and carbon storage. Our results ( i ) imply that under past or future warmer-than-present conditions, oceanic biogeochemical feedback mechanisms may change or even switch direction, and ( ii ) provide constraints on the high-latitude North Pacific's influence on mesopelagic ventilation dynamics, with consequences for large oceanic regions., Competing Interests: The authors declare no conflict of interest., (Copyright © 2018 the Author(s). Published by PNAS.)

Published
2018
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42. Glacial reduction and millennial-scale variations in Drake Passage throughflow.

Author

Lamy F, Arz HW, Kilian R, Lange CB, Lembke-Jene L, Wengler M, Kaiser J, Baeza-Urrea O, Hall IR, Harada N, and Tiedemann R

Abstract

The Drake Passage (DP) is the major geographic constriction for the Antarctic Circumpolar Current (ACC) and exerts a strong control on the exchange of physical, chemical, and biological properties between the Atlantic, Pacific, and Indian Ocean basins. Resolving changes in the flow of circumpolar water masses through this gateway is, therefore, crucial for advancing our understanding of the Southern Ocean's role in global ocean and climate variability. Here, we reconstruct changes in DP throughflow dynamics over the past 65,000 y based on grain size and geochemical properties of sediment records from the southernmost continental margin of South America. Combined with published sediment records from the Scotia Sea, we argue for a considerable total reduction of DP transport and reveal an up to ∼ 40% decrease in flow speed along the northernmost ACC pathway entering the DP during glacial times. Superimposed on this long-term decrease are high-amplitude, millennial-scale variations, which parallel Southern Ocean and Antarctic temperature patterns. The glacial intervals of strong weakening of the ACC entering the DP imply an enhanced export of northern ACC surface and intermediate waters into the South Pacific Gyre and reduced Pacific-Atlantic exchange through the DP ("cold water route"). We conclude that changes in DP throughflow play a critical role for the global meridional overturning circulation and interbasin exchange in the Southern Ocean, most likely regulated by variations in the westerly wind field and changes in Antarctic sea ice extent.

Published
2015
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