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Investigating ocean deoxygenation during the PETM through the Cr isotopic signature of foraminifera

Investigating ocean deoxygenation during the PETM through the Cr isotopic signature of foraminifera
Investigating ocean deoxygenation during the PETM through the Cr isotopic signature of foraminifera
Over the past several decades, oxygen minimum zones have rapidly expanded due to rising temperatures raising concerns about the impacts of future climate change. One way to better understand the drivers behind this expansion is to evaluate the links between climate and seawater deoxygenation in the past especially in times of geologically abrupt climate change such as the Palaeocene-Eocene Thermal Maximum (PETM), a well characterised period of rapid warming ~56 million years ago. We have developed and applied the novel redox proxies of foraminiferal Cr isotopes (δ53Cr) and Ce anomalies (Ce/Ce*) to assess changes in paleo-redox conditions arising from changes in oxygen availability. Both δ53Cr and Cr concentrations decrease notably over the PETM at intermediate to upper abyssal water depths, indicative of widespread reductions in dissolved oxygen concentrations. An apparent correlation between the sizes of δ53Cr and benthic δ18O excursions during the PETM suggests temperature is one of the main controlling factors of deoxygenation in the open ocean. ODP Sites 1210 in the Pacific and 1263 in the Southeast Atlantic suggest that deoxygenation is associated with warming and circulation changes, as supported by Ce/Ce* data. Our geochemical data are supported by simulations from an intermediate complexity climate model (cGENIE), which show that during the PETM anoxia was mostly restricted to the Tethys Sea, while hypoxia was more widespread as a result of increasing atmospheric CO2 (from 1 to 6 times pre-industrial values).
2572-4525
Remmelzwaal, Seginio
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Dixon, Sophie
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Parkinson, Ian
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Schmidt, Daniela
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Monteiro, Fanny
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Sexton, Philip
836b46d0-a948-4366-8cf6-73b7d30e651b
Fehr, Manuela
ee91ae90-29d6-483b-a37b-83985955eadc
Peacock, Caroline
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Donnadieu, Yannick
54586dcb-64b1-4c57-b780-2cb3ac04a7a5
James, Rachael
79aa1d5c-675d-4ba3-85be-fb20798c02f4
Remmelzwaal, Seginio
96a781f8-91e8-48e9-8f0b-f437877d4330
Dixon, Sophie
3c0f9618-9c42-4d53-98d9-ae02f2ca9207
Parkinson, Ian
b436d75d-5b39-4d00-ba2d-7e379afcf50b
Schmidt, Daniela
86a34245-7197-4ad2-984c-40374fe00b60
Monteiro, Fanny
9b43dc43-0369-403e-a47a-83eca4935ec5
Sexton, Philip
836b46d0-a948-4366-8cf6-73b7d30e651b
Fehr, Manuela
ee91ae90-29d6-483b-a37b-83985955eadc
Peacock, Caroline
35996b6e-4fe6-4b4b-914f-e473f0cc6bbf
Donnadieu, Yannick
54586dcb-64b1-4c57-b780-2cb3ac04a7a5
James, Rachael
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Remmelzwaal, Seginio, Dixon, Sophie, Parkinson, Ian, Schmidt, Daniela, Monteiro, Fanny, Sexton, Philip, Fehr, Manuela, Peacock, Caroline, Donnadieu, Yannick and James, Rachael (2019) Investigating ocean deoxygenation during the PETM through the Cr isotopic signature of foraminifera. Paleoceanography and Paleoclimatology. (doi:10.1029/2018PA003372).

Record type: Article

Abstract

Over the past several decades, oxygen minimum zones have rapidly expanded due to rising temperatures raising concerns about the impacts of future climate change. One way to better understand the drivers behind this expansion is to evaluate the links between climate and seawater deoxygenation in the past especially in times of geologically abrupt climate change such as the Palaeocene-Eocene Thermal Maximum (PETM), a well characterised period of rapid warming ~56 million years ago. We have developed and applied the novel redox proxies of foraminiferal Cr isotopes (δ53Cr) and Ce anomalies (Ce/Ce*) to assess changes in paleo-redox conditions arising from changes in oxygen availability. Both δ53Cr and Cr concentrations decrease notably over the PETM at intermediate to upper abyssal water depths, indicative of widespread reductions in dissolved oxygen concentrations. An apparent correlation between the sizes of δ53Cr and benthic δ18O excursions during the PETM suggests temperature is one of the main controlling factors of deoxygenation in the open ocean. ODP Sites 1210 in the Pacific and 1263 in the Southeast Atlantic suggest that deoxygenation is associated with warming and circulation changes, as supported by Ce/Ce* data. Our geochemical data are supported by simulations from an intermediate complexity climate model (cGENIE), which show that during the PETM anoxia was mostly restricted to the Tethys Sea, while hypoxia was more widespread as a result of increasing atmospheric CO2 (from 1 to 6 times pre-industrial values).

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Accepted/In Press date: 17 December 2018
e-pub ahead of print date: 3 May 2019

Identifiers

Local EPrints ID: 430769
URI: http://eprints.soton.ac.uk/id/eprint/430769
ISSN: 2572-4525
PURE UUID: a4055ab8-ca8d-4700-b60b-faaf03035c7b
ORCID for Rachael James: ORCID iD orcid.org/0000-0001-7402-2315

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Date deposited: 10 May 2019 16:30
Last modified: 16 Mar 2024 07:50

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Contributors

Author: Seginio Remmelzwaal
Author: Sophie Dixon
Author: Ian Parkinson
Author: Daniela Schmidt
Author: Fanny Monteiro
Author: Philip Sexton
Author: Manuela Fehr
Author: Caroline Peacock
Author: Yannick Donnadieu
Author: Rachael James ORCID iD

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