Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event

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Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event. / Dahl, Tais Wittchen; Boyle, Richard A.; Canfield, Donald E.; Connelly, James; Gill, Benjamin C.; Lenton, Timothy M.; Bizzarro, Martin.

In: Earth and Planetary Science Letters, Vol. 401, 01.09.2014, p. 313-326.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Dahl, TW, Boyle, RA, Canfield, DE, Connelly, J, Gill, BC, Lenton, TM & Bizzarro, M 2014, 'Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event', Earth and Planetary Science Letters, vol. 401, pp. 313-326. https://doi.org/10.1016/j.epsl.2014.05.043

APA

Dahl, T. W., Boyle, R. A., Canfield, D. E., Connelly, J., Gill, B. C., Lenton, T. M., & Bizzarro, M. (2014). Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event. Earth and Planetary Science Letters, 401, 313-326. https://doi.org/10.1016/j.epsl.2014.05.043

Vancouver

Dahl TW, Boyle RA, Canfield DE, Connelly J, Gill BC, Lenton TM et al. Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event. Earth and Planetary Science Letters. 2014 Sep 1;401:313-326. https://doi.org/10.1016/j.epsl.2014.05.043

Author

Dahl, Tais Wittchen ; Boyle, Richard A. ; Canfield, Donald E. ; Connelly, James ; Gill, Benjamin C. ; Lenton, Timothy M. ; Bizzarro, Martin. / Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event. In: Earth and Planetary Science Letters. 2014 ; Vol. 401. pp. 313-326.

Bibtex

@article{f54ecef70a604feda4343f9da0fd52b4,
title = "Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event",
abstract = "Anoxic marine zones were common in early Paleozoic oceans (542-400 Ma), and present a potential link to atmospheric pO2 via feedbacks linking global marine phosphorous recycling, primary production and organic carbon burial. Uranium (U) isotopes in carbonate rocks track the extent of ocean anoxia, whereas carbon (C) and sulfur (S) isotopes track the burial of organic carbon and pyrite sulfur (primary long-term sources of atmospheric oxygen). In combination, these proxies therefore reveal the comparative dynamics of ocean anoxia and oxygen liberation to the atmosphere over million-year time scales. Here we report high-precision uranium isotopic data in marine carbonates deposited during the Late Cambrian 'SPICE' event, at ca. 499 Ma, documenting a well-defined -0.18‰ negative δ238U excursion that occurs at the onset of the SPICE event's positive δ13C and δ34S excursions, but peaks (and tails off) before them. Dynamic modelling shows that the different response of the U reservoir cannot be attributed solely to differences in residence times or reservoir sizes - suggesting that two chemically distinct ocean states occurred within the SPICE event. The first ocean stage involved a global expansion of euxinic waters, triggering the spike in U burial, and peaking in conjunction with a well-known trilobite extinction event. During the second stage widespread euxinia waned, causing U removal to tail off, but enhanced organic carbon and pyrite burial continued, coinciding with evidence for severe sulfate depletion in the oceans (Gill et al., 2011). We discuss scenarios for how an interval of elevated pyrite and organic carbon burial could have been sustained without widespread euxinia in the water column (both non-sulfidic anoxia and/or a more oxygenated ocean state are possibilities). Either way, the SPICE event encompasses two different stages of elevated organic carbon and pyrite burial maintained by high nutrient fluxes to the ocean, and potentially sustained by internal marine geochemical feedbacks.",
keywords = "Anoxic marine zones, Carbonates, Oceanic anoxic events, Paleoredox, SPICE event, Uranium isotopes",
author = "Dahl, {Tais Wittchen} and Boyle, {Richard A.} and Canfield, {Donald E.} and James Connelly and Gill, {Benjamin C.} and Lenton, {Timothy M.} and Martin Bizzarro",
year = "2014",
month = sep,
day = "1",
doi = "10.1016/j.epsl.2014.05.043",
language = "English",
volume = "401",
pages = "313--326",
journal = "Earth and Planetary Science Letters",
issn = "0012-821X",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Uranium isotopes distinguish two geochemically distinct stages during the later Cambrian SPICE event

AU - Dahl, Tais Wittchen

AU - Boyle, Richard A.

AU - Canfield, Donald E.

AU - Connelly, James

AU - Gill, Benjamin C.

AU - Lenton, Timothy M.

AU - Bizzarro, Martin

PY - 2014/9/1

Y1 - 2014/9/1

N2 - Anoxic marine zones were common in early Paleozoic oceans (542-400 Ma), and present a potential link to atmospheric pO2 via feedbacks linking global marine phosphorous recycling, primary production and organic carbon burial. Uranium (U) isotopes in carbonate rocks track the extent of ocean anoxia, whereas carbon (C) and sulfur (S) isotopes track the burial of organic carbon and pyrite sulfur (primary long-term sources of atmospheric oxygen). In combination, these proxies therefore reveal the comparative dynamics of ocean anoxia and oxygen liberation to the atmosphere over million-year time scales. Here we report high-precision uranium isotopic data in marine carbonates deposited during the Late Cambrian 'SPICE' event, at ca. 499 Ma, documenting a well-defined -0.18‰ negative δ238U excursion that occurs at the onset of the SPICE event's positive δ13C and δ34S excursions, but peaks (and tails off) before them. Dynamic modelling shows that the different response of the U reservoir cannot be attributed solely to differences in residence times or reservoir sizes - suggesting that two chemically distinct ocean states occurred within the SPICE event. The first ocean stage involved a global expansion of euxinic waters, triggering the spike in U burial, and peaking in conjunction with a well-known trilobite extinction event. During the second stage widespread euxinia waned, causing U removal to tail off, but enhanced organic carbon and pyrite burial continued, coinciding with evidence for severe sulfate depletion in the oceans (Gill et al., 2011). We discuss scenarios for how an interval of elevated pyrite and organic carbon burial could have been sustained without widespread euxinia in the water column (both non-sulfidic anoxia and/or a more oxygenated ocean state are possibilities). Either way, the SPICE event encompasses two different stages of elevated organic carbon and pyrite burial maintained by high nutrient fluxes to the ocean, and potentially sustained by internal marine geochemical feedbacks.

AB - Anoxic marine zones were common in early Paleozoic oceans (542-400 Ma), and present a potential link to atmospheric pO2 via feedbacks linking global marine phosphorous recycling, primary production and organic carbon burial. Uranium (U) isotopes in carbonate rocks track the extent of ocean anoxia, whereas carbon (C) and sulfur (S) isotopes track the burial of organic carbon and pyrite sulfur (primary long-term sources of atmospheric oxygen). In combination, these proxies therefore reveal the comparative dynamics of ocean anoxia and oxygen liberation to the atmosphere over million-year time scales. Here we report high-precision uranium isotopic data in marine carbonates deposited during the Late Cambrian 'SPICE' event, at ca. 499 Ma, documenting a well-defined -0.18‰ negative δ238U excursion that occurs at the onset of the SPICE event's positive δ13C and δ34S excursions, but peaks (and tails off) before them. Dynamic modelling shows that the different response of the U reservoir cannot be attributed solely to differences in residence times or reservoir sizes - suggesting that two chemically distinct ocean states occurred within the SPICE event. The first ocean stage involved a global expansion of euxinic waters, triggering the spike in U burial, and peaking in conjunction with a well-known trilobite extinction event. During the second stage widespread euxinia waned, causing U removal to tail off, but enhanced organic carbon and pyrite burial continued, coinciding with evidence for severe sulfate depletion in the oceans (Gill et al., 2011). We discuss scenarios for how an interval of elevated pyrite and organic carbon burial could have been sustained without widespread euxinia in the water column (both non-sulfidic anoxia and/or a more oxygenated ocean state are possibilities). Either way, the SPICE event encompasses two different stages of elevated organic carbon and pyrite burial maintained by high nutrient fluxes to the ocean, and potentially sustained by internal marine geochemical feedbacks.

KW - Anoxic marine zones

KW - Carbonates

KW - Oceanic anoxic events

KW - Paleoredox

KW - SPICE event

KW - Uranium isotopes

U2 - 10.1016/j.epsl.2014.05.043

DO - 10.1016/j.epsl.2014.05.043

M3 - Journal article

C2 - 25684783

AN - SCOPUS:84903697250

VL - 401

SP - 313

EP - 326

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

SN - 0012-821X

ER -

ID: 123824170