Role of degassing of the Noril’sk nickel deposits in the Permian–Triassic mass extinction event

Vaillant, Margaux Le; Mungall, James E.; Mungall, Emma L.

doi:10.1073/pnas.1611086114

Cited by 69 publications

(44 citation statements)

References 28 publications

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“…Our proposed "sulfide buoyancy aid" process, operating from the metasomatized lithospheric mantle through to base of the continental crust, is analogous to the established mechanism where aqueous or saline vapor bubbles are suggested to "float" sulfide and/or magnetite at mid-upper crustal depths 12,14,15,17 . However, the critical difference is the deeper lithospheric window where this process operates, which provides a first order mechanism to fertilize the continental crust with mantle-derived chalcophile and siderophile metals.…”

Section: Discussionmentioning

confidence: 70%

“…Although supercritical CO 2 seems to be most critical for the transport of sulfides at mantle and lower crustal conditions, its solubility and low preservation potential increases the likelihood that H 2 O or other volatiles may overprint any originally C-driven textural signature and erase any geological record of its former occurrence. In such cases, other phases may appear to be the dominant volatiles preserved within upper crustal sulfide occurrences (e.g., hydrous silicate caps 15 ), rather than CO 2 . The preservation of intimately associated sulfide-carbonate in the upper crust is thus rare and the opportunity for study inherently limited.…”

Section: Discussionmentioning

confidence: 99%

“…In the upper crust, hydrous volatile phases have been demonstrated experimentally to provide a viable mechanism of upward physical transport for relatively dense sulfide liquid droplets 12 , 13 and magnetite crystals 14 . Empirically, this process is reflected in the recent identification of sulfides in magmatic systems associated with coarse-grained hydrous silicate caps 15 – 17 . In these cases, there is a strong physical attraction of sulfides and oxides to low-density hydrous or saline bubbles or droplets.…”

Section: Introductionmentioning

confidence: 99%

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Fluxing of mantle carbon as a physical agent for metallogenic fertilization of the crust

et al. 2020

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Magmatic systems play a crucial role in enriching the crust with volatiles and elements that reside primarily within the Earth's mantle, including economically important metals like nickel, copper and platinum-group elements. However, transport of these metals within silicate magmas primarily occurs within dense sulfide liquids, which tend to coalesce, settle and not be efficiently transported in ascending magmas. Here we show textural observations, backed up with carbon and oxygen isotope data, which indicate an intimate association between mantle-derived carbonates and sulfides in some mafic-ultramafic magmatic systems emplaced at the base of the continental crust. We propose that carbon, as a buoyant supercritical CO 2 fluid, might be a covert agent aiding and promoting the physical transport of sulfides across the mantle-crust transition. This may be a common but cryptic mechanism that facilitates cycling of volatiles and metals from the mantle to the lower-to-mid continental crust, which leaves little footprint behind by the time magmas reach the Earth's surface.

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Section: Discussionmentioning

confidence: 70%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fluxing of mantle carbon as a physical agent for metallogenic fertilization of the crust

et al. 2020

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“…A close association between sulfide globules and vapor phase has been already documented in experimental samples by Mungall et al (2015), who proposed that droplets of sulfide melt can attach to vapor bubbles and float through the magma. Natural samples from Noril'sk area also show textural evidence for sulfide flotation, suggesting S and Ni degassing during the crystallization of the orebearing intrusions (Le Vaillant et al, 2017). A complete model of S partitioning is required to simulate S distribution between the fluid phase, the silicate melt and the sulfide liquid, and to estimate sulfide melt production in the magma due to the assimilation of organic compounds.…”

Section: Discussionmentioning

confidence: 99%

Assimilation of sulfate and carbonaceous rocks: Experimental study, thermodynamic modeling and application to the Noril’sk-Talnakh region (Russia)

Iacono-Marziano

Ferraina

Gaillard

et al. 2017

Ore Geology Reviews

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This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. sulfate and organic matter-rich sedimentary rocks has been proposed as a possible mechanism for the origin of these exceptional sulfide deposits but the interaction process and the reaction paths have never been fully investigated. Here we clarify, by both experimental petrology and thermodynamic modeling, how sulfate and organic matter assimilation occur in mafic-ultramafic magmas, affecting magma composition, crystallization and sulfide saturation.Interaction experiments were conducted at conditions relevant to the emplacement of Noril'sk type intrusions (1200 °C, ~80 MPa) to simulate the assimilation of sulfate and/or organic compounds by ultramafic magmas. We used a picrite from Noril'sk1 intrusion, and coal and anhydrite from the area as starting materials. The experimental results show that the incorporation of anhydrite into the magma occurs by chemical dissolution in the melt, which increases the magma's sulfur content, but suppresses sulfide saturation and reduces olivine crystallization. Extreme assimilation leads to sulfate saturation in the magma and high dissolved sulfur contents of 0.9±0.1 wt.% S. Conversely, coal assimilation promotes sulfide segregation and magma crystallization, while decreasing the dissolved H 2 O content of the melt and increasing the amount of coexisting fluid phase.We also employed gas-melt thermodynamic calculations to quantify the effect of these assimilations on the redox conditions and the S content of the magma, and investigate the role of temperature, pressure, and initial gas content of the magma in the assimilation process. We quantify how sulfate assimilation strongly oxidizes the magma and increases its S content; both effects are intensified by 2 increasing pressure (from 50 to 100 MPa in this study), decreasing temperature (from 1350 to 1200 °C in this study), and decreasing amounts of fluid phase initially coexisting with the magma (from 2 to 0 wt.%). The interaction with organic matter (CH in this study) induces a strong reduction of the magma, even for extremely low degrees of assimilation (few tenths of wt. %), and the dehydration of the melt.We therefore suggest that in the Noril'sk-Talnakh district (1) additional S was supplied to mantle derived magmas by the assimilation of evaporitic rocks, and was transported during magma ascent in the form of dissolved, oxidized S; (2) a substantial reduction of the magma inducing sulfide segregation and important crystallization then occurred due to the interaction with carbonaceous sediments. This mechanism can potentially produce massive sulfide deposits by imp...

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“…Other observations of the Permian-Triassic boundary include 3) the presence of pyrite framboids in marine sediments indicating an anoxic event that was remarkably shallow and sudden during the interval (Wignall & Hallam, 1992;Wignall & Twitchett, 2002;Wignall et al 2005;Shen et al 2007;Kakuwa, 2008;Bond & Wignall, 2010;Brennecka et al 2011;Schoepfer et al 2012;Schoepfer et al 2013;Liao et al 2017), and 4) a dramatic decrease in carbonate deposition indicating increasing acidity in the world's ocean, and shallowing of the carbonate compensation depth (CCD; Kakuwa, 1996;Kershaw et al 1999;Payne et al 2007). More recently discovered indicators include 5) a 3-fold increase in mercury (Hg) restricted to the boundary layer (Sanei et al 2012;Grasby et al 2016); and 6) a 3 to 10-fold increase in nickel (Ni) and zinc (Zn) within the boundary layer (Liu et al 2017;Rampino et al 2017), which is interpreted as a result of volcanic ash fallout from the Siberian Traps large igneous province eruptions (Le Vaillant et al 2017).…”

Section: Introductionmentioning

confidence: 99%

What caused Earth's largest mass extinction event? New evidence from the Permian-Triassic boundary in northeastern Utah

Burger

Estrada

Gustin

2019

Global and Planetary Change

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This pre-print details the geochemistry across a newly discovered extraordinarily wellpreserved stratigraphic section of the Permian-Triassic boundary in Utah. The attached manuscript features a comprehensive geochemical dataset from northeastern Utah, assembled from a unique and remarkable 9-meter section of rock in Sheep Creek Valley. The findings include a large-scale carbon isotopic excursion across the event, indicative of high atmospheric carbon dioxide, as well as a dramatic reduction in the deposition of calcium carbonate due to ocean acidification at the boundary layer. This study further documents an elevated mercuryspike, as well as observed elevated lead, zinc and strontium content. This evidence suggests large amounts of naturally occurring emissions of coal combustion at the Permian-Triassic boundary, likely caused by the large scale volcanic eruptions of the coeval Siberian Traps. The resulting global changes associated with the abrupt enrichment of the atmosphere in carbon dioxide was the major contributor to the mass extinction event. This is the first study to examine barium content across the Permian-Triassic boundary, and it provides evidence that upwelling of methane hydrate in the oceans followed the initial acidification event. Ocean anoxia (absence of oxygen) is suggested by the unusual deposition of pyrite within the shallow marine waters of the once coastal sediments of northeastern Utah. Precession orbital geochemical variation is observed in the stratigraphic section allowing a finer temporal resolution beyond any previously published section. Together, this dataset gives a unique picture of an ancient cataclysm that altered life on Earth. This study is a cautionary tell of what can happen if we do not heed the warnings of the geological past. In Payne and Clapham's 2012 review of the Permian-Triassic boundary they suggested "the end-Permian extinction may serve as an important ancient analog for the twenty-first century…." The results of this study amplify that statement, as evidence gathered in this study suggest that large emissions of burning coal and other hydrocarbons during the Siberian Trap volcanic event was largely responsible for Earth's largest mass extinction 252 million years ago. A greater understanding of this ancient event may be the key in helping researchers forecast changes facing the Earth today.

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Role of degassing of the Noril’sk nickel deposits in the Permian–Triassic mass extinction event

Cited by 69 publications

References 28 publications

Fluxing of mantle carbon as a physical agent for metallogenic fertilization of the crust

Fluxing of mantle carbon as a physical agent for metallogenic fertilization of the crust

Assimilation of sulfate and carbonaceous rocks: Experimental study, thermodynamic modeling and application to the Noril’sk-Talnakh region (Russia)

What caused Earth's largest mass extinction event? New evidence from the Permian-Triassic boundary in northeastern Utah

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