Deoxygenation and organic carbon sequestration in the Tethyan realm associated with the middle Eocene climatic optimum
Cramwinckel, Margot J.; van der Ploeg, Robin; van Helmond, Niels A.G.M.; Waarlo, Niels; Agnini, Claudia; Bijl, Peter K.; van der Boon, Annique; Brinkhuis, Henk; Frieling, Joost; Krijgsman, Wout; Mather, Tamsin A.; Middelburg, Jack J.; Peterse, Francien; Slomp, Caroline P.; Sluijs, Appy
(2023) Bulletin of the Geological Society of America, volume 135, issue 5-6, pp. 1280 - 1296
(Article)
Abstract
The middle Eocene climatic optimum (ca. 40 Ma) stands out as a transient global warming phase of ~400 k.y. duration that interrupted long-term Eocene cooling; it has been associated with a rise in atmospheric CO2 concentrations that has been linked to a flare-up in Arabia-Eurasia continental arc volcanism. Increased organic
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carbon burial in the Tethys Ocean has been proposed as a carbon sequestration mechanism to bring the middle Eocene climatic optimum to an end. To further test these hypotheses, we assessed the sedimentary and geochemical expression of the middle Eocene climatic optimum in the northern Peri-Tethys, specifically, the organic-rich Kuma Formation of the Belaya River section, located on the edge of the Scythian Platform in the North Caucasus, Russia. We constructed an age-depth model using nannofossil chronobiostratigraphy. Throughout the studied middle Eocene interval (41.2–39.9 Ma), we documented sea-surface temperatures of 32–36 °C based on the tetraether index of tetraethers consisting of 86 carbons (TEX86), depending on proxy calibration, and during the early middle Eocene climatic optimum, we observed sea-surface warming of 2–3 °C. Despite the proximity of the section to the Arabia-Eurasia volcanic arc, the hypothesized source of volcanic CO2, we found no evidence for enhanced regional volcanism in sedimentary mercury concentrations. Sedimentary trace-element concentrations and iron speciation indicate reducing bottom waters throughout the middle Eocene, but the most reducing, even euxinic, conditions were reached during late middle Eocene climatic optimum cooling. This apparent regional decoupling between ocean warming and deoxygenation hints at a role for regional tectonics in causing basin restriction and anoxia. Associated excess organic carbon burial, extrapolated to the entire regional Kuma Formation, may have been ~8.1 Tg C yr–1, comprising ~450 Pg C over this ~55 k.y. interval. Combined with evidence for enhanced organic carbon drawdown in the western Peri-Tethys, this supports a quantitatively significant role for the basin in the termination of the middle Eocene climatic optimum by acting as a large organic carbon sink, and these results collectively illustrate that the closing Tethys Ocean might have affected global Paleogene climate.
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Keywords: Atmospheric mercury, Bacterial gmgts, Biomarker paleothermometry, Dinoflagellate cysts, Glycerol ether lipids, North caucasus, Proxy data, Southwest pacific, Thermal maximum, Water-column, Geology
ISSN: 0016-7606
Publisher: Geological Society of America
Note: Funding Information: This work was carried out under the program of the Netherlands Earth System Science Centre (NESSC), financially supported by the Dutch Ministry of Education, Culture and Science. We thank Sergey Popov and Larisa Golovina (Russian Academy of Sciences), Michael Morton and Sarah Davies (University of Leicester), Arjen Grothe and Kevin Vis (Utrecht University), and Stephen Vincent (Cambridge Arctic Shelf Programme, CASP, University of Cambridge) for field support and discussions. We thank Kirsten de Haan, Arnold van Dijk, Coen Mulder, and Natasja Welters (Utrecht University) for analytical support. T.A. Mather and J. Frieling acknowledge funding from a European Research Council (ERC) consolidator grant (ERC-2018-COG-818717-V-ECHO), A. Sluijs acknowledges ERC consolidator grant 771497 (SPANC), and C.P. Slomp and N.A.G.M. van Hel-mond acknowledge funding from Dutch Research Council (NWO) Vici grant 865.13.005. M.J. Cram-winckel and A. Sluijs thank the Ammodo Foundation for funding unfettered research by laureate A. Sluijs. Funding Information: This work was carried out under the program of the Netherlands Earth System Science Centre (NESSC), financially supported by the Dutch Ministry of Education, Culture and Science. We thank Sergey Popov and Larisa Golovina (Russian Academy of Sciences), Michael Morton and Sarah Davies (University of Leicester), Arjen Grothe and Kevin Vis (Utrecht University), and Stephen Vincent (Cambridge Arctic Shelf Programme, CASP, University of Cambridge) for field support and discussions. We thank Kirsten de Haan, Arnold van Dijk, Coen Mulder, and Natasja Welters (Utrecht University) for analytical support. T.A. Mather and J. Frieling acknowledge funding from a European Research Council (ERC) consolidator grant (ERC-2018-COG-818717-V-ECHO), A. Sluijs acknowledges ERC consolidator grant 771497 (SPANC), and C.P. Slomp and N.A.G.M. van Helmond acknowledge funding from Dutch Research Council (NWO) Vici grant 865.13.005. M.J. Cramwinckel and A. Sluijs thank the Ammodo Foundation for funding unfettered research by laureate A. Sluijs Publisher Copyright: © 2022 The Authors. Gold Open Access: This paper is published under the terms of the CC-BY license
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