Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a)

L.M.E. Percival; L.R. Tedeschi; R.A. Creaser; C. Bottini; E. Erba; F. Giraud; H. Svensen; J. Savian; R. Trindade; R. Coccioni; F. Frontalini; L. Jovane; T.A. Mather; H.C. Jenkyns

doi:10.1016/j.gloplacha.2021.103461

Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a)

L.M.E. Percival, L.R. Tedeschi, R.A. Creaser, C. Bottini, E. Erba, F. Giraud, H. Svensen, J. Savian, R. Trindade, R. Coccioni, F. Frontalini, L. Jovane, T.A. Mather, H.C. Jenkyns

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

Abstract

Large igneous province (LIP) volcanism has been proposed as a key trigger of several major climate and environmental perturbations during the Phanerozoic Aeon. Large-scale carbon emissions associated with one or both of magmatic degassing from the Greater Ontong-Java Plateau (G-OJP) and intrusion of organic-rich sediments by High Arctic LIP (HALIP) sills have been widely suggested as the trigger of the Early Aptian Oceanic Anoxic Event (OAE 1a: ~120 Ma). However, the respective roles of the two LIPs and associated carbon sources in causing this crisis remain debated. Here, six records of OAE 1a from the Pacific, Tethyan, Arctic, and South Atlantic realms are investigated, combining mercury (Hg) concentrations and osmium- (Os-) isotope ratios as proxies of LIP activity. Together with previously published datasets, the results indicate globally consistent Os-isotope evidence for LIP activity during OAE 1a, but geographically variable stratigraphic Hg trends. Clear mercury enrichments that match Os-isotope evidence of LIP activity, and suggest a Hg-cycle perturbation during the onset of OAE 1a, are documented at one Pacific site extremely proximal to the G-OJP, but not in Arctic, Tethyan or Atlantic records. This pattern highlights significant G-OJP volcanism during the onset of OAE 1a, and re-emphasises the limited potential for submarine LIP eruptions to cause Hg-cycle perturbations except in areas very proximal to source. The absence of clear Hg peaks in basal OAE 1a strata from the Arctic (or anywhere outside of the Pacific) does not support intense HALIP activity at that time, suggesting that the G-OJP was the more volcanically active LIP when OAE 1a commenced. Thus, G-OJP emissions of mantle carbon were more likely to have played a major role in initiating OAE 1a than thermogenic volatiles associated with the HALIP. A transient pulse of HALIP-related subaerial eruptions and/or thermogenic volatile emissions during the early–middle part of OAE 1a, potentially evidenced by more widespread Hg enrichments in strata from that time (including in the Arctic), might have prolonged the event. However, a non-volcanic cause of these later Hg influxes cannot be excluded. These findings challenge previous suggestions that magmatic CO2 emissions from LIPs were incapable of causing major carbon-cycle perturbations alone, and highlight the need for further investigations to establish whether the high volume/emplacement rate of the G-OJP (potentially an order of magnitude greater than other LIPs) made it a unique case that stands in contrast to other provinces where the role of thermogenic volatiles was likely more crucial.

Original language	English
Article number	103461
Journal	Global and Planetary Change
Volume	200
DOIs	https://doi.org/10.1016/j.gloplacha.2021.103461
Publication status	Published - 1 May 2021
Externally published	Yes

Funding

We greatly appreciate feedback from J.M. Castro and one anonymous reviewer that has improved this manuscript. We gratefully acknowledge John Farmer and the University of Edinburgh for provision of geochemical standard material, Stéphane Reboulet for fieldwork assistance at the Notre-Dame-de-Rosans section, and Steve Wyatt for aiding laboratory analyses. The Poggio le Guaine (PLG) core drilling was financially supported by the Fundação de Apoio à Universidade de São Paulo and Petrobras grant 2405. Peter Szatmari is thanked for conducting the logistical arrangements required to perform rhenium-osmium analyses on PLG samples at the University of Alberta. The UNIS CO2 Lab is thanked for providing access to the DH-1 core samples, and we greatly appreciate assistance from Sverre Planke, Ivar Midtkandal, and Stéphane Polteau in sampling the core. We thank the UK Natural Environment Research Council (NERC) grant NE/G01700X/1 (to Tamsin Mather), the European Research Council consolidator grant ERC-2018-COG-B18717-V-ECHO (to Tamsin Mather), NERC PhD studentship NE/L501530/1 (to Lawrence Percival), the Flanders Research Foundation (FWO) grant no. 12P4519N (to Lawrence Percival), the MIURPRIN (Ministero dell'Istruzione, dell'Università e della Ricerca–Progetti di Ricerca di Interesse Nazionale): grant no. PRIN 2017RX9XXXY to Elisabetta Erba, the Research Council of Norway Centres of Excellence (Project 223272 to Henrik Svensen), Petrobras (for financial support of the PLG and Petrobras Well D analyses and doctoral student funding for Leonardo R. Tedeschi), the Vrije Universiteit Brussel, and the Leverhulme Trust for funding. We greatly appreciate feedback from J.M. Castro and one anonymous reviewer that has improved this manuscript. We gratefully acknowledge John Farmer and the University of Edinburgh for provision of geochemical standard material, Stéphane Reboulet for fieldwork assistance at the Notre-Dame-de-Rosans section, and Steve Wyatt for aiding laboratory analyses. The Poggio le Guaine (PLG) core drilling was financially supported by the Fundação de Apoio à Universidade de São Paulo and Petrobras grant 2405 . Peter Szatmari is thanked for conducting the logistical arrangements required to perform rhenium-osmium analyses on PLG samples at the University of Alberta. The UNIS CO2 Lab is thanked for providing access to the DH-1 core samples, and we greatly appreciate assistance from Sverre Planke, Ivar Midtkandal, and Stéphane Polteau in sampling the core. We thank the UK Natural Environment Research Council (NERC) grant NE/G01700X/1 (to Tamsin Mather), the European Research Council consolidator grant ERC-2018-COG-B18717-V-ECHO (to Tamsin Mather), NERC PhD studentship NE/L501530/1 (to Lawrence Percival), the Flanders Research Foundation (FWO) grant no. 12P4519N (to Lawrence Percival), the MIURPRIN (Ministero dell'Istruzione, dell'Università e della Ricerca–Progetti di Ricerca di Interesse Nazionale) : grant no. PRIN 2017RX9XXXY to Elisabetta Erba, the Research Council of Norway Centres of Excellence (Project 223272 to Henrik Svensen), Petrobras (for financial support of the PLG and Petrobras Well D analyses and doctoral student funding for Leonardo R. Tedeschi), the Vrije Universiteit Brussel , and the Leverhulme Trust for funding.

Funders	Funder number
Fundação de Apoio à Universidade de São Paulo and Petrobras	2405
MIURPRIN
Research Council of Norway Centres of Excellence	223272
Horizon 2020 Framework Programme	818717
University of Alberta
Natural Environment Research Council	NE/G01700X/1
Leverhulme Trust
European Research Council	ERC-2018-COG-B18717-V-ECHO
University of Edinburgh
Fonds Wetenschappelijk Onderzoek	12P4519N
Ministero dell’Istruzione, dell’Università e della Ricerca
Petrobras
Vrije Universiteit Brussel

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Percival, L. M. E., Tedeschi, L. R., Creaser, R. A., Bottini, C., Erba, E., Giraud, F., Svensen, H., Savian, J., Trindade, R., Coccioni, R., Frontalini, F., Jovane, L., Mather, T. A., & Jenkyns, H. C. (2021). Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a). Global and Planetary Change, 200, Article 103461. https://doi.org/10.1016/j.gloplacha.2021.103461

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title = "Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a)",

abstract = "Large igneous province (LIP) volcanism has been proposed as a key trigger of several major climate and environmental perturbations during the Phanerozoic Aeon. Large-scale carbon emissions associated with one or both of magmatic degassing from the Greater Ontong-Java Plateau (G-OJP) and intrusion of organic-rich sediments by High Arctic LIP (HALIP) sills have been widely suggested as the trigger of the Early Aptian Oceanic Anoxic Event (OAE 1a: ~120 Ma). However, the respective roles of the two LIPs and associated carbon sources in causing this crisis remain debated. Here, six records of OAE 1a from the Pacific, Tethyan, Arctic, and South Atlantic realms are investigated, combining mercury (Hg) concentrations and osmium- (Os-) isotope ratios as proxies of LIP activity. Together with previously published datasets, the results indicate globally consistent Os-isotope evidence for LIP activity during OAE 1a, but geographically variable stratigraphic Hg trends. Clear mercury enrichments that match Os-isotope evidence of LIP activity, and suggest a Hg-cycle perturbation during the onset of OAE 1a, are documented at one Pacific site extremely proximal to the G-OJP, but not in Arctic, Tethyan or Atlantic records. This pattern highlights significant G-OJP volcanism during the onset of OAE 1a, and re-emphasises the limited potential for submarine LIP eruptions to cause Hg-cycle perturbations except in areas very proximal to source. The absence of clear Hg peaks in basal OAE 1a strata from the Arctic (or anywhere outside of the Pacific) does not support intense HALIP activity at that time, suggesting that the G-OJP was the more volcanically active LIP when OAE 1a commenced. Thus, G-OJP emissions of mantle carbon were more likely to have played a major role in initiating OAE 1a than thermogenic volatiles associated with the HALIP. A transient pulse of HALIP-related subaerial eruptions and/or thermogenic volatile emissions during the early–middle part of OAE 1a, potentially evidenced by more widespread Hg enrichments in strata from that time (including in the Arctic), might have prolonged the event. However, a non-volcanic cause of these later Hg influxes cannot be excluded. These findings challenge previous suggestions that magmatic CO2 emissions from LIPs were incapable of causing major carbon-cycle perturbations alone, and highlight the need for further investigations to establish whether the high volume/emplacement rate of the G-OJP (potentially an order of magnitude greater than other LIPs) made it a unique case that stands in contrast to other provinces where the role of thermogenic volatiles was likely more crucial.",

author = "L.M.E. Percival and L.R. Tedeschi and R.A. Creaser and C. Bottini and E. Erba and F. Giraud and H. Svensen and J. Savian and R. Trindade and R. Coccioni and F. Frontalini and L. Jovane and T.A. Mather and H.C. Jenkyns",

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Percival, LME, Tedeschi, LR, Creaser, RA, Bottini, C, Erba, E, Giraud, F, Svensen, H, Savian, J, Trindade, R, Coccioni, R, Frontalini, F, Jovane, L, Mather, TA & Jenkyns, HC 2021, 'Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a)', Global and Planetary Change, vol. 200, 103461. https://doi.org/10.1016/j.gloplacha.2021.103461

TY - JOUR

T1 - Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a)

AU - Percival, L.M.E.

AU - Tedeschi, L.R.

AU - Creaser, R.A.

AU - Bottini, C.

AU - Erba, E.

AU - Giraud, F.

AU - Svensen, H.

AU - Savian, J.

AU - Trindade, R.

AU - Coccioni, R.

AU - Frontalini, F.

AU - Jovane, L.

AU - Mather, T.A.

AU - Jenkyns, H.C.

PY - 2021/5/1

Y1 - 2021/5/1

N2 - Large igneous province (LIP) volcanism has been proposed as a key trigger of several major climate and environmental perturbations during the Phanerozoic Aeon. Large-scale carbon emissions associated with one or both of magmatic degassing from the Greater Ontong-Java Plateau (G-OJP) and intrusion of organic-rich sediments by High Arctic LIP (HALIP) sills have been widely suggested as the trigger of the Early Aptian Oceanic Anoxic Event (OAE 1a: ~120 Ma). However, the respective roles of the two LIPs and associated carbon sources in causing this crisis remain debated. Here, six records of OAE 1a from the Pacific, Tethyan, Arctic, and South Atlantic realms are investigated, combining mercury (Hg) concentrations and osmium- (Os-) isotope ratios as proxies of LIP activity. Together with previously published datasets, the results indicate globally consistent Os-isotope evidence for LIP activity during OAE 1a, but geographically variable stratigraphic Hg trends. Clear mercury enrichments that match Os-isotope evidence of LIP activity, and suggest a Hg-cycle perturbation during the onset of OAE 1a, are documented at one Pacific site extremely proximal to the G-OJP, but not in Arctic, Tethyan or Atlantic records. This pattern highlights significant G-OJP volcanism during the onset of OAE 1a, and re-emphasises the limited potential for submarine LIP eruptions to cause Hg-cycle perturbations except in areas very proximal to source. The absence of clear Hg peaks in basal OAE 1a strata from the Arctic (or anywhere outside of the Pacific) does not support intense HALIP activity at that time, suggesting that the G-OJP was the more volcanically active LIP when OAE 1a commenced. Thus, G-OJP emissions of mantle carbon were more likely to have played a major role in initiating OAE 1a than thermogenic volatiles associated with the HALIP. A transient pulse of HALIP-related subaerial eruptions and/or thermogenic volatile emissions during the early–middle part of OAE 1a, potentially evidenced by more widespread Hg enrichments in strata from that time (including in the Arctic), might have prolonged the event. However, a non-volcanic cause of these later Hg influxes cannot be excluded. These findings challenge previous suggestions that magmatic CO2 emissions from LIPs were incapable of causing major carbon-cycle perturbations alone, and highlight the need for further investigations to establish whether the high volume/emplacement rate of the G-OJP (potentially an order of magnitude greater than other LIPs) made it a unique case that stands in contrast to other provinces where the role of thermogenic volatiles was likely more crucial.

AB - Large igneous province (LIP) volcanism has been proposed as a key trigger of several major climate and environmental perturbations during the Phanerozoic Aeon. Large-scale carbon emissions associated with one or both of magmatic degassing from the Greater Ontong-Java Plateau (G-OJP) and intrusion of organic-rich sediments by High Arctic LIP (HALIP) sills have been widely suggested as the trigger of the Early Aptian Oceanic Anoxic Event (OAE 1a: ~120 Ma). However, the respective roles of the two LIPs and associated carbon sources in causing this crisis remain debated. Here, six records of OAE 1a from the Pacific, Tethyan, Arctic, and South Atlantic realms are investigated, combining mercury (Hg) concentrations and osmium- (Os-) isotope ratios as proxies of LIP activity. Together with previously published datasets, the results indicate globally consistent Os-isotope evidence for LIP activity during OAE 1a, but geographically variable stratigraphic Hg trends. Clear mercury enrichments that match Os-isotope evidence of LIP activity, and suggest a Hg-cycle perturbation during the onset of OAE 1a, are documented at one Pacific site extremely proximal to the G-OJP, but not in Arctic, Tethyan or Atlantic records. This pattern highlights significant G-OJP volcanism during the onset of OAE 1a, and re-emphasises the limited potential for submarine LIP eruptions to cause Hg-cycle perturbations except in areas very proximal to source. The absence of clear Hg peaks in basal OAE 1a strata from the Arctic (or anywhere outside of the Pacific) does not support intense HALIP activity at that time, suggesting that the G-OJP was the more volcanically active LIP when OAE 1a commenced. Thus, G-OJP emissions of mantle carbon were more likely to have played a major role in initiating OAE 1a than thermogenic volatiles associated with the HALIP. A transient pulse of HALIP-related subaerial eruptions and/or thermogenic volatile emissions during the early–middle part of OAE 1a, potentially evidenced by more widespread Hg enrichments in strata from that time (including in the Arctic), might have prolonged the event. However, a non-volcanic cause of these later Hg influxes cannot be excluded. These findings challenge previous suggestions that magmatic CO2 emissions from LIPs were incapable of causing major carbon-cycle perturbations alone, and highlight the need for further investigations to establish whether the high volume/emplacement rate of the G-OJP (potentially an order of magnitude greater than other LIPs) made it a unique case that stands in contrast to other provinces where the role of thermogenic volatiles was likely more crucial.

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Determining the style and provenance of magmatic activity during the Early Aptian Oceanic Anoxic Event (OAE 1a)

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