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Molecular and isotopic evidence reveals the end-Triassic carbon isotope excursion is not from massive exogenous light carbon

Molecular and isotopic evidence reveals the end-Triassic carbon isotope excursion is not from massive exogenous light carbon
Molecular and isotopic evidence reveals the end-Triassic carbon isotope excursion is not from massive exogenous light carbon

The negative organic carbon isotope excursion (CIE) associated with the end-Triassic mass extinction (ETE) is conventionally interpreted as the result of a massive flux of isotopically light carbon from exogenous sources into the atmosphere (e.g., thermogenic methane and/or methane clathrate dissociation linked to the Central Atlantic Magmatic Province [CAMP]). Instead, we demonstrate that at its type locality in the Bristol Channel Basin (UK), the CIE was caused by a marine to nonmarine transition resulting from an abrupt relative sea level drop. Our biomarker and compound-specific carbon isotopic data show that the emergence of microbial mats, influenced by an influx of fresh to brackish water, provided isotopically light carbon to both organic and inorganic carbon pools in centimeter-scale water depths, leading to the negative CIE. Thus, the iconic CIE and the disappearance of marine biota at the type locality are the result of local environmental change and do not mark either the global extinction event or input of exogenous light carbon into the atmosphere. Instead, the main extinction phase occurs slightly later in marine strata, where it is coeval with terrestrial extinctions and ocean acidification driven by CAMP-induced increases in PCO2; these effects should not be conflated with the CIE. An abrupt sea-level fall observed in the Central European basins reflects the tectonic consequences of the initial CAMP emplacement, with broad implications for all extinction events related to large igneous provinces.

biomarkers, carbon isotopes, end-Triassic mass extinction, large igneous provinces
0027-8424
30171-30178
Fox, Calum P.
11adb22e-5474-4e6a-966a-c5da6090b352
Cui, Xingqian
40f9d5f2-7146-4e64-9ffe-fcd9589787db
Whiteside, Jessica H.
5d9ad7aa-eba3-4ad9-9f6f-81be71b6829b
Olsen, Paul E.
bdbec40b-82ed-41ac-8028-b6c333206f16
Summons, Roger E.
9c032a63-ac8f-4c68-959c-e7848e5eacaf
Grice, Kliti
81653f25-68b0-4da0-b8e2-34211dbc5239
Fox, Calum P.
11adb22e-5474-4e6a-966a-c5da6090b352
Cui, Xingqian
40f9d5f2-7146-4e64-9ffe-fcd9589787db
Whiteside, Jessica H.
5d9ad7aa-eba3-4ad9-9f6f-81be71b6829b
Olsen, Paul E.
bdbec40b-82ed-41ac-8028-b6c333206f16
Summons, Roger E.
9c032a63-ac8f-4c68-959c-e7848e5eacaf
Grice, Kliti
81653f25-68b0-4da0-b8e2-34211dbc5239

Fox, Calum P., Cui, Xingqian, Whiteside, Jessica H., Olsen, Paul E., Summons, Roger E. and Grice, Kliti (2020) Molecular and isotopic evidence reveals the end-Triassic carbon isotope excursion is not from massive exogenous light carbon. Proceedings of the National Academy of Sciences, 117 (48), 30171-30178. (doi:10.1073/pnas.1917661117).

Record type: Article

Abstract

The negative organic carbon isotope excursion (CIE) associated with the end-Triassic mass extinction (ETE) is conventionally interpreted as the result of a massive flux of isotopically light carbon from exogenous sources into the atmosphere (e.g., thermogenic methane and/or methane clathrate dissociation linked to the Central Atlantic Magmatic Province [CAMP]). Instead, we demonstrate that at its type locality in the Bristol Channel Basin (UK), the CIE was caused by a marine to nonmarine transition resulting from an abrupt relative sea level drop. Our biomarker and compound-specific carbon isotopic data show that the emergence of microbial mats, influenced by an influx of fresh to brackish water, provided isotopically light carbon to both organic and inorganic carbon pools in centimeter-scale water depths, leading to the negative CIE. Thus, the iconic CIE and the disappearance of marine biota at the type locality are the result of local environmental change and do not mark either the global extinction event or input of exogenous light carbon into the atmosphere. Instead, the main extinction phase occurs slightly later in marine strata, where it is coeval with terrestrial extinctions and ocean acidification driven by CAMP-induced increases in PCO2; these effects should not be conflated with the CIE. An abrupt sea-level fall observed in the Central European basins reflects the tectonic consequences of the initial CAMP emplacement, with broad implications for all extinction events related to large igneous provinces.

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Fox_2020_PNAS_06_10_2020_main_text_SI_final_3_ - Accepted Manuscript
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Accepted/In Press date: 13 October 2020
e-pub ahead of print date: 16 November 2020
Published date: 1 December 2020
Additional Information: Funding Information: ACKNOWLEDGMENTS. We acknowledge Peter Hopper, Alex Holman, and P. Sargent Bray for technical support and Victor Leshyk for schematics. C.P.F. acknowledges Curtin University for an international scholarship (this paper forms a fundamental chapter of C.P.F.’s thesis). C.P.F. (PhD scholarship) and K.G. (funding for Triassic/Jurassic) acknowledge the Australian Research Council (ARC) for Linkage funding (Grant LP150100341) supporting this work. K.G. acknowledges the ARC for three infrastructure grants for CSIA (Grant LE110100119) and bulk isotope work (Grants LE100100041 and LE0882836). C.P.F. acknowledges the European Association of Organic Geochemistry for a travel scholarship award. J.H.W. and R.E.S. acknowledge support from NSF Grant EAR 1147402. X.C. and R.E.S. acknowledge the Simons Foundation Collaboration on the Origins of Life (Grant 290361FY18). P.E.O. acknowledges fieldwork support from the Lamont Climate Center. C.P.F. also acknowledges Khalifa University of Science and Technology (Grant CIRA-2019-066). We are grateful to Bob Cornes of Natural England for permission to sample the foreshore in Somerset and guidance for sampling permission from the Orchard-Wyndham estate. We thank reviewers Simon George and Jennifer McElwain for their constructive comments, which helped significantly improve this manuscript. This is Lamont-Doherty Earth Observatory contribution 8454. Publisher Copyright: © 2020 National Academy of Sciences. All rights reserved.
Keywords: biomarkers, carbon isotopes, end-Triassic mass extinction, large igneous provinces

Identifiers

Local EPrints ID: 445401
URI: http://eprints.soton.ac.uk/id/eprint/445401
DOI: doi:10.1073/pnas.1917661117
ISSN: 0027-8424
PURE UUID: 3e73ca33-77ac-4a11-8d38-d832f43071f1

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Date deposited: 07 Dec 2020 17:32
Last modified: 17 Mar 2024 06:08

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Contributors

Author: Calum P. Fox
Author: Xingqian Cui
Author: Jessica H. Whiteside
Author: Paul E. Olsen
Author: Roger E. Summons
Author: Kliti Grice

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