Melting of sediments in the deep mantle produces saline fluid inclusions in diamonds

Michael W. Förster; Stephen F. Foley; Horst R. Marschall; Olivier Alard; Stephan Buhre

doi:10.1126/sciadv.aau2620

Melting of sediments in the deep mantle produces saline fluid inclusions in diamonds

Michael W. Förster^*, Stephen F. Foley, Horst R. Marschall, Olivier Alard, Stephan Buhre

^*Corresponding author for this work

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

23 Citations (Scopus)

Abstract

Diamonds growing in the Earth's mantle often trap inclusions of fluids that are highly saline in composition. These fluids are thought to emerge from deep in subduction zones and may also be involved in the generation of some of the kimberlite magmas. However, the source of these fluids and the mechanism of their transport into the mantle lithosphere are unresolved. Here, we present experimental results showing that alkali chlorides are stable solid phases in the mantle lithosphere below 110 km. These alkali chlorides are formed by the reaction of subducted marine sediments with peridotite and show identical K/Na ratios to fluid inclusions in diamond. At temperatures >1100°C and low pressures, the chlorides are unstable; here, potassium is accommodated in mica and melt. The reaction of subducted sediments with peridotite explains the occurrence of Mg carbonates and the highly saline fluids found in diamonds and in chlorine-enriched kimberlite magmas.

Original language	English
Article number	aau2620
Journal	Science advances
Volume	5
Issue number	5
DOIs	https://doi.org/10.1126/sciadv.aau2620
Publication status	Published - 2019
Externally published	Yes

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title = "Melting of sediments in the deep mantle produces saline fluid inclusions in diamonds",

abstract = "Diamonds growing in the Earth's mantle often trap inclusions of fluids that are highly saline in composition. These fluids are thought to emerge from deep in subduction zones and may also be involved in the generation of some of the kimberlite magmas. However, the source of these fluids and the mechanism of their transport into the mantle lithosphere are unresolved. Here, we present experimental results showing that alkali chlorides are stable solid phases in the mantle lithosphere below 110 km. These alkali chlorides are formed by the reaction of subducted marine sediments with peridotite and show identical K/Na ratios to fluid inclusions in diamond. At temperatures >1100°C and low pressures, the chlorides are unstable; here, potassium is accommodated in mica and melt. The reaction of subducted sediments with peridotite explains the occurrence of Mg carbonates and the highly saline fluids found in diamonds and in chlorine-enriched kimberlite magmas.",

author = "F{\"o}rster, {Michael W.} and Foley, {Stephen F.} and Marschall, {Horst R.} and Olivier Alard and Stephan Buhre",

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doi = "10.1126/sciadv.aau2620",

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AU - Förster, Michael W.

AU - Foley, Stephen F.

AU - Marschall, Horst R.

AU - Alard, Olivier

AU - Buhre, Stephan

PY - 2019

Y1 - 2019

N2 - Diamonds growing in the Earth's mantle often trap inclusions of fluids that are highly saline in composition. These fluids are thought to emerge from deep in subduction zones and may also be involved in the generation of some of the kimberlite magmas. However, the source of these fluids and the mechanism of their transport into the mantle lithosphere are unresolved. Here, we present experimental results showing that alkali chlorides are stable solid phases in the mantle lithosphere below 110 km. These alkali chlorides are formed by the reaction of subducted marine sediments with peridotite and show identical K/Na ratios to fluid inclusions in diamond. At temperatures >1100°C and low pressures, the chlorides are unstable; here, potassium is accommodated in mica and melt. The reaction of subducted sediments with peridotite explains the occurrence of Mg carbonates and the highly saline fluids found in diamonds and in chlorine-enriched kimberlite magmas.

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Melting of sediments in the deep mantle produces saline fluid inclusions in diamonds

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