Journal
EARTH AND PLANETARY SCIENCE LETTERS
Volume 291, Issue 1-4, Pages 84-96Publisher
ELSEVIER
DOI: 10.1016/j.epsl.2009.12.053
Keywords
Spitsbergen; Permian; Triassic; biomarker; carbon isotopes; hydrogen isotopes; sulfur isotopes; photic zone euxinia; methane clathrates
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Funding
- ARC [DP0211875, DP0877167]
- Curtin University of Technology
- Institute for Geoscience Research (TIGER)
- NASA
- Australian Research Council [DP0877167, DP0211875] Funding Source: Australian Research Council
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The largest extinction of the Phanerozoic occurred near the Permian/Triassic (P/Tr) boundary some 252 Ma ago. Several scenarios and drivers have been proposed for this event. Here we report for the first time an integrated study comprising sedimentological data, biomarker distributions/abundances and selected stable carbon and hydrogen isotopes along with bulk isotopes (delta S-34(pyrite), delta C-13(carb), delta C-13(org)) for a Late Permian section from Lusitaniadalen, Spitsbergen, Norway. Sedimentological and geochemical data support a marine transgression and collapse of the marine ecosystem in the Late Permian. Strong evidence for waxing and waning of photic zone euxinia throughout the Late Permian is provided by Chlorobiaceae-derived biomarkers (including delta C-13 data) and delta S-34(pyrite), implying multiple phases of H2S outgassing and potentially several pulses of extinction. A rapid decrease in abundance of various land-plant biomarkers prior to the marine collapse event indicates a dramatic decline of land-plants during the Late Permian and/or increasing distance from palaeoshoreline as a consequence of sea level rise. Changes in delta D of selected biomarkers also suggest a change in source of organic matter (CM) or sea level rise. We also found biomarker and isotopic evidence for a phytoplanktonic bloom triggered by eutrophication as a consequence of the marine collapse. Compound specific isotope analyses (CSIA) of algal and land-plant-derived biomarkers, as well as delta C-13 of carbonate and bulk OM provide strong evidence for synchronous changes in delta C-13 of marine and atmospheric CO2, attributed to a C-13-depleted source. The source could be associated with isotopically depleted methane released from the melting of gas clathrates and/or from respired CM, due to collapse of the marine ecosystem. (c) 2010 Published by Elsevier B.V.
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