Incipient carbonate melting drives metal and sulfur mobilization in the mantle

Isra S. Ezad; Martin Saunders; Svyatoslav S. Shcheka; Marco L. Fiorentini; Lauren R. Gorojovsky; Michael W. Förster; Stephen F. Foley

doi:10.1126/sciadv.adk5979

Incipient carbonate melting drives metal and sulfur mobilization in the mantle

Isra S. Ezad, Martin Saunders, Svyatoslav S. Shcheka, Marco L. Fiorentini, Lauren R. Gorojovsky, Michael W. Förster, Stephen F. Foley

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

We present results from high-pressure, high-temperature experiments that generate incipient carbonate melts at mantle conditions (~90 kilometers depth and temperatures between 750° and 1050°C). We show that these primitive carbonate melts can sequester sulfur in its oxidized form of sulfate, as well as base and precious metals from mantle lithologies of peridotite and pyroxenite. It is proposed that these carbonate sulfur–rich melts may be more widespread than previously thought and that they may play a first-order role in the metallogenic enhancement of localized lithospheric domains. They act as effective agents to dissolve, redistribute, and concentrate metals within discrete domains of the mantle and into shallower regions within Earth, where dynamic physicochemical processes can lead to ore genesis at various crustal depths.

Original language	English
Number of pages	12
Journal	Science Advances
Volume	10
Issue number	12
DOIs	https://doi.org/10.1126/sciadv.adk5979
Publication status	Published - 22 Mar 2024

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abstract = "We present results from high-pressure, high-temperature experiments that generate incipient carbonate melts at mantle conditions (~90 kilometers depth and temperatures between 750° and 1050°C). We show that these primitive carbonate melts can sequester sulfur in its oxidized form of sulfate, as well as base and precious metals from mantle lithologies of peridotite and pyroxenite. It is proposed that these carbonate sulfur–rich melts may be more widespread than previously thought and that they may play a first-order role in the metallogenic enhancement of localized lithospheric domains. They act as effective agents to dissolve, redistribute, and concentrate metals within discrete domains of the mantle and into shallower regions within Earth, where dynamic physicochemical processes can lead to ore genesis at various crustal depths.",

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AU - Ezad, Isra S.

AU - Saunders, Martin

AU - Shcheka, Svyatoslav S.

AU - Fiorentini, Marco L.

AU - Gorojovsky, Lauren R.

AU - Förster, Michael W.

AU - Foley, Stephen F.

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AB - We present results from high-pressure, high-temperature experiments that generate incipient carbonate melts at mantle conditions (~90 kilometers depth and temperatures between 750° and 1050°C). We show that these primitive carbonate melts can sequester sulfur in its oxidized form of sulfate, as well as base and precious metals from mantle lithologies of peridotite and pyroxenite. It is proposed that these carbonate sulfur–rich melts may be more widespread than previously thought and that they may play a first-order role in the metallogenic enhancement of localized lithospheric domains. They act as effective agents to dissolve, redistribute, and concentrate metals within discrete domains of the mantle and into shallower regions within Earth, where dynamic physicochemical processes can lead to ore genesis at various crustal depths.

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Incipient carbonate melting drives metal and sulfur mobilization in the mantle

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