Marine anoxia and delayed Earth system recovery after the end-Permian extinction

Marine anoxia and delayed Earth system recovery after the end-Permian extinction

Delayed Earth system recovery following the end-Permian mass extinction is often attributed to severe ocean anoxia. However, the extent and duration of Early Triassic anoxia remains poorly constrained. Here we use paired records of uranium concentrations ([U]) and 238U/235U isotopic compositions (δ2...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 113; no. 9; pp. 2360 - 2365
Main Authors: Lau, Kimberly V., Maher, Kate, Altiner, Demir, Kelley, Brian M., Kump, Lee R., Lehrmann, Daniel J., Silva-Tamayo, Juan Carlos, Weaver, Karrie L., Yu, Meiyi, Payne, Jonathan L.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 01-03-2016
National Acad Sciences
Subjects:
Earth
Earth (Planet)
Ecosystem
Extinction
Extinction, Biological
Geological time
Isotopes
Oxygen - analysis
Physical Sciences
Seawater
uranium isotopes
biogeochemical cycling
carbon isotopes
Early Triassic
paleoredox
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Summary:Delayed Earth system recovery following the end-Permian mass extinction is often attributed to severe ocean anoxia. However, the extent and duration of Early Triassic anoxia remains poorly constrained. Here we use paired records of uranium concentrations ([U]) and 238U/235U isotopic compositions (δ238U) of Upper Permian−Upper Triassic marine limestones from China and Turkey to quantify variations in global seafloor redox conditions. We observe abrupt decreases in [U] and δ238U across the end-Permian extinction horizon, from ∼3 ppm and −0.15‰ to ∼0.3 ppm and −0.77‰, followed by a gradual return to preextinction values over the subsequent 5 million years. These trends imply a factor of 100 increase in the extent of seafloor anoxia and suggest the presence of a shallow oxygen minimum zone (OMZ) that inhibited the recovery of benthic animal diversity and marine ecosystem function. We hypothesize that in the Early Triassic oceans—characterized by prolonged shallow anoxia that may have impinged onto continental shelves—global biogeochemical cycles and marine ecosystem structure became more sensitive to variation in the position of the OMZ. Under this hypothesis, the Middle Triassic decline in bottom water anoxia, stabilization of biogeochemical cycles, and diversification of marine animals together reflect the development of a deeper and less extensive OMZ, which regulated Earth system recovery following the end-Permian catastrophe.
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Edited by Paul F. Hoffman, University of Victoria, Victoria, British Columbia, Canada, and approved January 8, 2016 (received for review August 1, 2015)
Author contributions: K.V.L., K.M., and J.L.P. designed research; K.V.L. performed research; K.V.L., K.M., L.R.K., and J.L.P. analyzed data; K.V.L., K.M., D.A., L.R.K., D.J.L., J.C.S.-T., K.L.W., and J.L.P. wrote the paper; D.A., B.M.K., D.J.L., and M.Y. provided samples and stratigraphic data; L.R.K. contributed to data interpretation and modeling; and J.C.S.-T. contributed to data interpretation.
2Present address: ExxonMobil Upstream Research Company, Houston TX 77389.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1515080113