Sulfide-rich continental roots at cratonic margins formed by carbonated melts

Chen, Chunfei; Förster, Michael W.; Shcheka, Svyatoslav S.; Ezad, Isra S.; Shea, Joshua J.; Liu, Yongsheng; Jacob, Dorrit E.; Foley, Stephen F.

Sulfide-rich continental roots at cratonic margins formed by carbonated melts

Chunfei Chen (), Michael W. Förster, Svyatoslav S. Shcheka, Isra S. Ezad, Joshua J. Shea, Yongsheng Liu, Dorrit E. Jacob and Stephen F. Foley
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Chunfei Chen: China University of Geosciences
Michael W. Förster: Macquarie University
Svyatoslav S. Shcheka: Macquarie University
Isra S. Ezad: The university of Western Australia
Joshua J. Shea: Macquarie University
Yongsheng Liu: China University of Geosciences
Dorrit E. Jacob: Australian National University
Stephen F. Foley: Macquarie University

Nature, 2025, vol. 637, issue 8046, 615-621

Abstract: Abstract The cratonic crust contains abundant mineral deposits of metals such as gold, copper and rare earths1–5 and is underlain by a thick mantle lithosphere rich in the volatiles carbon, sulfur and water6–8. Although volatiles are known to be key components in metallogenesis9, how and where they are distributed in the cratonic lithosphere mantle and their role in the initial enrichment of metals have not been sufficiently explored. Here we compile sulfur and copper contents of global cratonic peridotites, identifying sulfide-rich and copper-rich continental roots at depths of 160–190 km at cratonic margins. Our new high-pressure experiments show that carbonated silicate melts originating from the asthenosphere lose silicate components during reaction with lithospheric peridotite, evolving to carbonatite melts that become concentrated at cratonic margins. Sulfur solubility in melts substantially decreases as the SiO2 content of melts decreases during this process, forcing sulfide precipitation and the formation of sulfide-rich continental roots at the base of the mantle lithosphere. The migration of carbonated melts towards cratonic margins replenishes the continental roots there with sulfur, explaining the co-location of magmatic metal deposits with carbonatites close to cratonic margins. These findings highlight the notable role of carbonated melts in metallogenesis and provide a potential platform for metal ore exploration.

Date: 2025
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DOI: 10.1038/s41586-024-08316-w

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