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Woodland, Alan B., Girnis, Andrei V., Bulatov, Vadim K., Brey, Gerhard P., Höfer, Heidi E. (2020) Breyite inclusions in diamond: experimental evidence for possible dual origin. European Journal of Mineralogy, 32 (1) 171-185 doi:10.5194/ejm-32-171-2020

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Reference TypeJournal (article/letter/editorial)
TitleBreyite inclusions in diamond: experimental evidence for possible dual origin
JournalEuropean Journal of Mineralogy
AuthorsWoodland, Alan B.Author
Girnis, Andrei V.Author
Bulatov, Vadim K.Author
Brey, Gerhard P.Author
Höfer, Heidi E.Author
Year2020 (February 11)Volume32
Issue1
PublisherCopernicus GmbH
Download URLhttps://ejm.copernicus.org/articles/32/171/2020/ejm-32-171-2020.pdf+
DOIdoi:10.5194/ejm-32-171-2020Search in ResearchGate
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Mindat Ref. ID129898Long-form Identifiermindat:1:5:129898:1
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Full ReferenceWoodland, Alan B., Girnis, Andrei V., Bulatov, Vadim K., Brey, Gerhard P., Höfer, Heidi E. (2020) Breyite inclusions in diamond: experimental evidence for possible dual origin. European Journal of Mineralogy, 32 (1) 171-185 doi:10.5194/ejm-32-171-2020
Plain TextWoodland, Alan B., Girnis, Andrei V., Bulatov, Vadim K., Brey, Gerhard P., Höfer, Heidi E. (2020) Breyite inclusions in diamond: experimental evidence for possible dual origin. European Journal of Mineralogy, 32 (1) 171-185 doi:10.5194/ejm-32-171-2020
In(2020) European Journal of Mineralogy Vol. 32 (1) Schweizerbart
Abstract/NotesInclusions of breyite (previously known as walstromite-structured CaSiO3) in diamond are usually interpreted as retrogressed CaSiO3 perovskite trapped in the transition zone or the lower mantle. However, the thermodynamic stability field of breyite does not preclude its crystallization together with diamond under upper-mantle conditions (6–10 GPa). The possibility of breyite forming in subducted sedimentary material through the reaction CaCO3 + SiO2 = CaSiO3 + C + O2 was experimentally evaluated in the CaO–SiO2–C–O2 ± H2O system at 6–10 GPa, 900–1500 ∘C and oxygen fugacity 0.5–1.0 log units below the Fe–FeO (IW) buffer. One experimental series was conducted in the anhydrous subsystem and aimed at determining the melting temperature of the aragonite–coesite (or stishovite) assemblage. It was found that melting occurs at a lower temperature (∼1500 ∘C) than the decarbonation reaction, which indicates that breyite cannot be formed from aragonite and silica under anhydrous conditions and an oxygen fugacity above IW – 1. In the second experimental series, we investigated partial melting of an aragonite–coesite mixture under hydrous conditions at the same pressures and redox conditions. The melting temperature in the presence of water decreased strongly (to 900–1200 ∘C), and the melt had a hydrous silicate composition. The reduction of melt resulted in graphite crystallization in equilibrium with titanite-structured CaSi2O5 and breyite at ∼1000 ∘C. The maximum pressure of possible breyite formation is limited by the reaction CaSiO3 + SiO2 = CaSi2O5 at ∼8 GPa. Based on the experimental results, it is concluded that breyite inclusions found in natural diamond may be formed from an aragonite–coesite assemblage or carbonate melt at 6–8 GPa via reduction at high water activity.

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Breyite

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Bulatov, V. K., Girnis, A. V., Brey, G. P., Woodland, A. B., Höfer, H. E. (2019) Ferropericlase crystallization under upper mantle conditions. Contributions to Mineralogy and Petrology, 174 (5) doi:10.1007/s00410-019-1582-6
Brey, G. P., Girnis, A. V., Bulatov, V. K., Höfer, H. E., Gerdes, A., Woodland, A. B. (2015) Reduced sediment melting at 7.5–12 GPa: phase relations, geochemical signals and diamond nucleation. Contributions to Mineralogy and Petrology, 170 (2) doi:10.1007/s00410-015-1166-z
Brey, Gerhard P., Bulatov, Vadim K., Girnis, Andrei V. (2009) Influence of water and fluorine on melting of carbonated peridotite at 6 and 10 GPa. Lithos, 112. 249-259 doi:10.1016/j.lithos.2009.04.037
Matjuschkin, Vladimir, Brey, Gerhard P., Höfer, Heidi E., Woodland, Alan B. (2014) The influence of Fe3+ on garnet–orthopyroxene and garnet–olivine geothermometers. Contributions to Mineralogy and Petrology, 167 (2) doi:10.1007/s00410-014-0972-z
Brey, Gerhard P., Bulatov, Vadim K., Girnis, Andrei V. (2011) Melting of K-rich carbonated peridotite at 6–10GPa and the stability of K-phases in the upper mantle. Chemical Geology, 281 (3) 333-342 doi:10.1016/j.chemgeo.2010.12.019
Brey, Gerhard P., Bulatov, Vadim, Girnis, Andrei, Harris, Jeff W., Stachel, Thomas (2004) Ferropericlase—a lower mantle phase in the upper mantle. Lithos, 77 (1) 655-663 doi:10.1016/j.lithos.2004.03.013
Girnis, A. V., Woodland, A. B., Bulatov, V. K., Brey, G. P., Höfer, H. E. (2022) Redox Freezing and Melting during Peridotite Interaction with Carbonated Metasediments and Metabasics: Experiments at 10 GPa. Geochemistry International, 60 (7) 609-625 doi:10.1134/s0016702922070035
Höfer, Heidi E., Lazarov, Marina, Brey, Gerhard P., Woodland, Alan B. (2009) Oxygen fugacity of the metasomatizing melt in a polymict peridotite from Kimberley. Lithos, 112. 1150-1154 doi:10.1016/j.lithos.2009.05.037
Girnis, Andrei V., Brey, Gerhard P. (1999) Garnet-spinel-olivine-orthopyroxene equilibria in the FeO-MgO-Al2O3-SiO2-Cr2O3 system: II. Thermodynamic analysis. European Journal of Mineralogy, 11 (4) 619-636 doi:10.1127/ejm/11/4/0619
Girnis, A.V., Brey, G.P., Bulatov, V.K., Höfer, H.E., Woodland, A.B. (2018) Graphite to diamond transformation during sediment–peridotite interaction at 7.5 and 10.5 GPa. Lithos, 310. 302-313 doi:10.1016/j.lithos.2018.04.010
Woodland, A.B., Girnis, A.V., Bulatov, V.K., Brey, G.P., Höfer, H.E. (2019) Experimental study of sulfur solubility in silicate–carbonate melts at 5–10.5 GPa. Chemical Geology, 505. 12-22 doi:10.1016/j.chemgeo.2018.12.008
 
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