Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

Aidan Starr; Ian R. Hall; Stephen Barker; Thomas Rackow; Xu Zhang; Sidney R. Hemming; H. J.L. van der Lubbe; Gregor Knorr; Melissa A. Berke; Grant R. Bigg; Alejandra Cartagena-Sierra; Francisco J. Jiménez-Espejo; Xun Gong; Jens Gruetzner; Nambiyathodi Lathika; Leah J. LeVay; Rebecca S. Robinson; Martin Ziegler; Expedition 361 Science Party

doi:10.1038/s41586-020-03094-7

Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

Aidan Starr^*, Ian R. Hall, Stephen Barker, Thomas Rackow, Xu Zhang, Sidney R. Hemming, H. J.L. van der Lubbe, Gregor Knorr, Melissa A. Berke, Grant R. Bigg, Alejandra Cartagena-Sierra, Francisco J. Jiménez-Espejo, Xun Gong, Jens Gruetzner, Nambiyathodi Lathika, Leah J. LeVay, Rebecca S. Robinson, Martin Ziegler, Expedition 361 Science Party

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today¹; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled². An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to ‘escape’ into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the ‘southern escape’ and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the ‘100-kyr world’, in which glacial–interglacial cycles occur at roughly 100,000-year periods.

Original language	English
Article number	7841
Pages (from-to)	236-241
Number of pages	6
Journal	Nature
Volume	589
Issue number	7841
DOIs	https://doi.org/10.1038/s41586-020-03094-7
Publication status	Published - 14 Jan 2021

Bibliographical note

Funding Information:
Acknowledgements This research used samples and/or data provided by the International Ocean Discovery Program (IODP). Funding for this research was provided by The Natural Environmental Research Council GW4+ Doctoral Training Partnership (A.S.) and NERC grant NE/P000037/1 (I.R.H.). A.S. acknowledges further funding through the Antarctic Science International Bursary. X.Z. acknowledges funding from Lanzhou University (number 225000-830006) and National Key R&D programme of China (number 2018YFA0606403). F.J.J.-E. acknowledges funding through Spanish Ministry of Science and Innovation (grant CTM2017-89711-C2-1-P), co-funded by the European Union through FEDER funds. G.K. acknowledges funding by the German Helmholtz national REKLIM initiative and the BMBF project PalMod. L. Owen, S. Slater, A. Nedebragt and D. Muir are thanked for laboratory assistance.

Publisher Copyright:
© 2020, The Author(s), under exclusive licence to Springer Nature Limited.

Funding

Acknowledgements This research used samples and/or data provided by the International Ocean Discovery Program (IODP). Funding for this research was provided by The Natural Environmental Research Council GW4+ Doctoral Training Partnership (A.S.) and NERC grant NE/P000037/1 (I.R.H.). A.S. acknowledges further funding through the Antarctic Science International Bursary. X.Z. acknowledges funding from Lanzhou University (number 225000-830006) and National Key R&D programme of China (number 2018YFA0606403). F.J.J.-E. acknowledges funding through Spanish Ministry of Science and Innovation (grant CTM2017-89711-C2-1-P), co-funded by the European Union through FEDER funds. G.K. acknowledges funding by the German Helmholtz national REKLIM initiative and the BMBF project PalMod. L. Owen, S. Slater, A. Nedebragt and D. Muir are thanked for laboratory assistance.

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10.1038/s41586-020-03094-7

s41586-020-03094-7Final published version, 9.9 MBLicence: Taverne

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Starr, A., Hall, I. R., Barker, S., Rackow, T., Zhang, X., Hemming, S. R., van der Lubbe, H. J. L., Knorr, G., Berke, M. A., Bigg, G. R., Cartagena-Sierra, A., Jiménez-Espejo, F. J., Gong, X., Gruetzner, J., Lathika, N., LeVay, L. J., Robinson, R. S., Ziegler, M., & Expedition 361 Science Party (2021). Antarctic icebergs reorganize ocean circulation during Pleistocene glacials. Nature, 589(7841), 236-241. Article 7841. https://doi.org/10.1038/s41586-020-03094-7

@article{3cc00749c8dd4d23acf0f267650ee2c7,

title = "Antarctic icebergs reorganize ocean circulation during Pleistocene glacials",

abstract = "The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today1; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled2. An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to {\textquoteleft}escape{\textquoteright} into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the {\textquoteleft}southern escape{\textquoteright} and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the {\textquoteleft}100-kyr world{\textquoteright}, in which glacial–interglacial cycles occur at roughly 100,000-year periods.",

author = "Aidan Starr and Hall, {Ian R.} and Stephen Barker and Thomas Rackow and Xu Zhang and Hemming, {Sidney R.} and {van der Lubbe}, {H. J.L.} and Gregor Knorr and Berke, {Melissa A.} and Bigg, {Grant R.} and Alejandra Cartagena-Sierra and Jim{\'e}nez-Espejo, {Francisco J.} and Xun Gong and Jens Gruetzner and Nambiyathodi Lathika and LeVay, {Leah J.} and Robinson, {Rebecca S.} and Martin Ziegler and {Expedition 361 Science Party} and Luna Brentegani and Thibaut Caley and Charles, {Christopher D.} and Coenen, {Jason J.} and Crespin, {Julien G.} and Franzese, {Allison M.} and Xibin Han and Hines, {Sophia K.V.} and {Jimenez Espejo}, {Francisco J.} and Janna Just and Andreas Koutsodendris and Kaoru Kubota and Norris, {Richard D.} and {dos Santos}, {Thiago Pereira} and Rolison, {John M.} and Simon, {Margit H.} and Deborah Tangunan and {van der Lubbe}, {H. J.L.} and Masako Yamane and Hucai Zhang",

note = "Funding Information: Acknowledgements This research used samples and/or data provided by the International Ocean Discovery Program (IODP). Funding for this research was provided by The Natural Environmental Research Council GW4+ Doctoral Training Partnership (A.S.) and NERC grant NE/P000037/1 (I.R.H.). A.S. acknowledges further funding through the Antarctic Science International Bursary. X.Z. acknowledges funding from Lanzhou University (number 225000-830006) and National Key R&D programme of China (number 2018YFA0606403). F.J.J.-E. acknowledges funding through Spanish Ministry of Science and Innovation (grant CTM2017-89711-C2-1-P), co-funded by the European Union through FEDER funds. G.K. acknowledges funding by the German Helmholtz national REKLIM initiative and the BMBF project PalMod. L. Owen, S. Slater, A. Nedebragt and D. Muir are thanked for laboratory assistance. Publisher Copyright: {\textcopyright} 2020, The Author(s), under exclusive licence to Springer Nature Limited.",

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doi = "10.1038/s41586-020-03094-7",

language = "English",

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Starr, A, Hall, IR, Barker, S, Rackow, T, Zhang, X, Hemming, SR, van der Lubbe, HJL, Knorr, G, Berke, MA, Bigg, GR, Cartagena-Sierra, A, Jiménez-Espejo, FJ, Gong, X, Gruetzner, J, Lathika, N, LeVay, LJ, Robinson, RS, Ziegler, M & Expedition 361 Science Party 2021, 'Antarctic icebergs reorganize ocean circulation during Pleistocene glacials', Nature, vol. 589, no. 7841, 7841, pp. 236-241. https://doi.org/10.1038/s41586-020-03094-7

TY - JOUR

T1 - Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

AU - Starr, Aidan

AU - Hall, Ian R.

AU - Barker, Stephen

AU - Rackow, Thomas

AU - Zhang, Xu

AU - Hemming, Sidney R.

AU - van der Lubbe, H. J.L.

AU - Knorr, Gregor

AU - Berke, Melissa A.

AU - Bigg, Grant R.

AU - Cartagena-Sierra, Alejandra

AU - Jiménez-Espejo, Francisco J.

AU - Gong, Xun

AU - Gruetzner, Jens

AU - Lathika, Nambiyathodi

AU - LeVay, Leah J.

AU - Robinson, Rebecca S.

AU - Ziegler, Martin

AU - Expedition 361 Science Party

AU - Brentegani, Luna

AU - Caley, Thibaut

AU - Charles, Christopher D.

AU - Coenen, Jason J.

AU - Crespin, Julien G.

AU - Franzese, Allison M.

AU - Han, Xibin

AU - Hines, Sophia K.V.

AU - Jimenez Espejo, Francisco J.

AU - Just, Janna

AU - Koutsodendris, Andreas

AU - Kubota, Kaoru

AU - Norris, Richard D.

AU - dos Santos, Thiago Pereira

AU - Rolison, John M.

AU - Simon, Margit H.

AU - Tangunan, Deborah

AU - van der Lubbe, H. J.L.

AU - Yamane, Masako

AU - Zhang, Hucai

N1 - Funding Information: Acknowledgements This research used samples and/or data provided by the International Ocean Discovery Program (IODP). Funding for this research was provided by The Natural Environmental Research Council GW4+ Doctoral Training Partnership (A.S.) and NERC grant NE/P000037/1 (I.R.H.). A.S. acknowledges further funding through the Antarctic Science International Bursary. X.Z. acknowledges funding from Lanzhou University (number 225000-830006) and National Key R&D programme of China (number 2018YFA0606403). F.J.J.-E. acknowledges funding through Spanish Ministry of Science and Innovation (grant CTM2017-89711-C2-1-P), co-funded by the European Union through FEDER funds. G.K. acknowledges funding by the German Helmholtz national REKLIM initiative and the BMBF project PalMod. L. Owen, S. Slater, A. Nedebragt and D. Muir are thanked for laboratory assistance. Publisher Copyright: © 2020, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2021/1/14

Y1 - 2021/1/14

N2 - The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today1; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled2. An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to ‘escape’ into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the ‘southern escape’ and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the ‘100-kyr world’, in which glacial–interglacial cycles occur at roughly 100,000-year periods.

AB - The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today1; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled2. An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to ‘escape’ into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the ‘southern escape’ and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the ‘100-kyr world’, in which glacial–interglacial cycles occur at roughly 100,000-year periods.

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U2 - 10.1038/s41586-020-03094-7

DO - 10.1038/s41586-020-03094-7

M3 - Article

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AN - SCOPUS:85099645114

SN - 0028-0836

VL - 589

SP - 236

EP - 241

JO - Nature

JF - Nature

IS - 7841

M1 - 7841

ER -

Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

Abstract

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