Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction

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Standard

Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction. / Richoz, S.; Van De Schootbrugge, B.; Pross, J.; Püttmann, W.; Quan, T.M.; Lindström, S.; Heunisch, C.; Fiebig, J.; Maquil, R.; Schouten, S.; Hauzenberger, C.A.; Wignall, P.B.

I: Nature Geoscience, Bind 5, 2012, s. 662-667.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Richoz, S, Van De Schootbrugge, B, Pross, J, Püttmann, W, Quan, TM, Lindström, S, Heunisch, C, Fiebig, J, Maquil, R, Schouten, S, Hauzenberger, CA & Wignall, PB 2012, 'Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction', Nature Geoscience, bind 5, s. 662-667. https://doi.org/10.1038/ngeo1539

APA

Richoz, S., Van De Schootbrugge, B., Pross, J., Püttmann, W., Quan, T. M., Lindström, S., Heunisch, C., Fiebig, J., Maquil, R., Schouten, S., Hauzenberger, C. A., & Wignall, P. B. (2012). Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction. Nature Geoscience, 5, 662-667. https://doi.org/10.1038/ngeo1539

Vancouver

Richoz S, Van De Schootbrugge B, Pross J, Püttmann W, Quan TM, Lindström S o.a. Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction. Nature Geoscience. 2012;5:662-667. https://doi.org/10.1038/ngeo1539

Author

Richoz, S. ; Van De Schootbrugge, B. ; Pross, J. ; Püttmann, W. ; Quan, T.M. ; Lindström, S. ; Heunisch, C. ; Fiebig, J. ; Maquil, R. ; Schouten, S. ; Hauzenberger, C.A. ; Wignall, P.B. / Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction. I: Nature Geoscience. 2012 ; Bind 5. s. 662-667.

Bibtex

@article{b68c9e5a43d344e5b46de486d084f5a8,
title = "Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction",
abstract = "The evolution of complex life over the past 600 million years was disrupted by at least five mass extinctions, one of which occurred at the close of the Triassic period. The end-Triassic extinction corresponds to a period of high atmospheric-CO2 concentrations caused by massive volcanism and biomass burning; most extinction scenarios invoke the resulting environmental perturbations in accounting for the loss of marine and terrestrial biodiversity. Here we reconstruct changes in Tethyan shallow marine ecosystems and ocean redox chemistry from earliest Jurassic (Hettangian)-aged black shales from Germany and Luxemburg. The shales contain increased concentrations of the biomarker isorenieratane, a fossilized pigment from green sulphur bacteria. The abundance of green sulphur bacteria suggests that the photic zone underwent prolonged periods of high concentrations of hydrogen sulphide. This interval is also marked by the proliferation of green algae, an indicator of anoxia. We conclude that the redox changes in the entire water column reflect sluggish circulation in marginal regions of the Tethys Ocean. We suggest that the resultant repeated poisoning of shallow epicontinental seas—hotspots of Mesozoic biodiversity—with hydrogen sulphide may have slowed the recovery of marine ecosystems during the Early Jurassic.",
author = "S. Richoz and {Van De Schootbrugge}, B. and J. Pross and W. P{\"u}ttmann and T.M. Quan and S. Lindstr{\"o}m and C. Heunisch and J. Fiebig and R. Maquil and S. Schouten and C.A. Hauzenberger and P.B. Wignall",
year = "2012",
doi = "10.1038/ngeo1539",
language = "English",
volume = "5",
pages = "662--667",
journal = "Nature Geoscience",
issn = "1752-0894",
publisher = "nature publishing group",

}

RIS

TY - JOUR

T1 - Hydrogen sulphide poisoning of shallow seas following the end-Triassic extinction

AU - Richoz, S.

AU - Van De Schootbrugge, B.

AU - Pross, J.

AU - Püttmann, W.

AU - Quan, T.M.

AU - Lindström, S.

AU - Heunisch, C.

AU - Fiebig, J.

AU - Maquil, R.

AU - Schouten, S.

AU - Hauzenberger, C.A.

AU - Wignall, P.B.

PY - 2012

Y1 - 2012

N2 - The evolution of complex life over the past 600 million years was disrupted by at least five mass extinctions, one of which occurred at the close of the Triassic period. The end-Triassic extinction corresponds to a period of high atmospheric-CO2 concentrations caused by massive volcanism and biomass burning; most extinction scenarios invoke the resulting environmental perturbations in accounting for the loss of marine and terrestrial biodiversity. Here we reconstruct changes in Tethyan shallow marine ecosystems and ocean redox chemistry from earliest Jurassic (Hettangian)-aged black shales from Germany and Luxemburg. The shales contain increased concentrations of the biomarker isorenieratane, a fossilized pigment from green sulphur bacteria. The abundance of green sulphur bacteria suggests that the photic zone underwent prolonged periods of high concentrations of hydrogen sulphide. This interval is also marked by the proliferation of green algae, an indicator of anoxia. We conclude that the redox changes in the entire water column reflect sluggish circulation in marginal regions of the Tethys Ocean. We suggest that the resultant repeated poisoning of shallow epicontinental seas—hotspots of Mesozoic biodiversity—with hydrogen sulphide may have slowed the recovery of marine ecosystems during the Early Jurassic.

AB - The evolution of complex life over the past 600 million years was disrupted by at least five mass extinctions, one of which occurred at the close of the Triassic period. The end-Triassic extinction corresponds to a period of high atmospheric-CO2 concentrations caused by massive volcanism and biomass burning; most extinction scenarios invoke the resulting environmental perturbations in accounting for the loss of marine and terrestrial biodiversity. Here we reconstruct changes in Tethyan shallow marine ecosystems and ocean redox chemistry from earliest Jurassic (Hettangian)-aged black shales from Germany and Luxemburg. The shales contain increased concentrations of the biomarker isorenieratane, a fossilized pigment from green sulphur bacteria. The abundance of green sulphur bacteria suggests that the photic zone underwent prolonged periods of high concentrations of hydrogen sulphide. This interval is also marked by the proliferation of green algae, an indicator of anoxia. We conclude that the redox changes in the entire water column reflect sluggish circulation in marginal regions of the Tethys Ocean. We suggest that the resultant repeated poisoning of shallow epicontinental seas—hotspots of Mesozoic biodiversity—with hydrogen sulphide may have slowed the recovery of marine ecosystems during the Early Jurassic.

U2 - 10.1038/ngeo1539

DO - 10.1038/ngeo1539

M3 - Journal article

VL - 5

SP - 662

EP - 667

JO - Nature Geoscience

JF - Nature Geoscience

SN - 1752-0894

ER -

ID: 290448797