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W1974872027 startingPage "17" @default.
W1974872027 abstract "We have experimentally determined the solidus of an alkali-bearing carbonated peridotite (with 5 wt.% CO2) between 10 and 20 GPa. Based on K-deficit in all low-temperature runs we assumed that some melt could be present in the low temperature runs and the true solidus of an alkali-bearing carbonated peridotite is placed below 1200 °C. However, based on the disappearance of magnesite and the appearance of the visible quenched melt coexisting with silicate phases, the ‘apparent’ solidus, which may be applicable for peridotite with low alkali contents, was identified. The ‘apparent’ solidus temperature increases from ~ 1380 °C at 10 GPa to ~ 1525 °C at 15 GPa and the ‘apparent’ solidus curve becomes almost flat from 15 GPa to 20 GPa, where it is located near 1550 °C. At 10 GPa, the ‘apparent’ solidus of carbonated peridotite is ~ 550 °C lower than the solidus of CO2-free natural anhydrous peridotite. The solidus of the present study was also ~ 120 °C lower than the solidus determined by Dasgupta and Hirschmann [Dasgupta, R., Hirschmann, M.M., 2006. Melting in the Earth's deep upper mantle caused by carbon dioxide. Nature, 440, 659–662.] for natural carbonated peridotite. The drop in the solidus temperature is mainly due to the effect of alkalis (Na2O, K2O). The melt near the ‘apparent’ solidus has high CO2 (> 40 wt.%) and contains < 6.0 wt.% SiO2, < 0.30 wt.% Al2O3 and < 0.25 wt.% TiO2. The composition of near-solidus partial melt is close to that observed at 6–10 GPa in the CMS-CO2 and CMAS-CO2 systems, and natural carbonated peridotite, with some variations in Ca/Mg-ratio. High alkali contents in measured and calculated partial melts are consistent with the compositions of deep-seated fluids observed as inclusions in diamonds and may be consistent with the compositions of parental melt, reconstructed for natural magnesiocarbonatite. We have demonstrated that magnesiocarbonatite-like melt can be generated by partial melting of carbonated peridotite at pressure up to at least 20 GPa. The generation of calciocarbonatite and ferrocarbonatite is unlikely to be possible during melting of carbonated peridotite in the deep mantle." @default.
W1974872027 created "2016-06-24" @default.
W1974872027 creator A5001259196 @default.
W1974872027 creator A5006341965 @default.
W1974872027 creator A5026621174 @default.
W1974872027 creator A5087076801 @default.
W1974872027 date "2009-05-01" @default.
W1974872027 modified "2023-10-14" @default.
W1974872027 title "Solidus of carbonated peridotite from 10 to 20 GPa and origin of magnesiocarbonatite melt in the Earth's deep mantle" @default.
W1974872027 cites W121579099 @default.
W1974872027 cites W1585654991 @default.
W1974872027 cites W1644176828 @default.
W1974872027 cites W1963585501 @default.
W1974872027 cites W1966086724 @default.
W1974872027 cites W1967541014 @default.
W1974872027 cites W1969206263 @default.
W1974872027 cites W1972871289 @default.
W1974872027 cites W1974767465 @default.
W1974872027 cites W1978140627 @default.
W1974872027 cites W1979335327 @default.
W1974872027 cites W1979776674 @default.
W1974872027 cites W1980445495 @default.
W1974872027 cites W1980952757 @default.
W1974872027 cites W1984885274 @default.
W1974872027 cites W1988488782 @default.
W1974872027 cites W1989054411 @default.
W1974872027 cites W1989637085 @default.
W1974872027 cites W1994135464 @default.
W1974872027 cites W1996000677 @default.
W1974872027 cites W1998264376 @default.
W1974872027 cites W2002443197 @default.
W1974872027 cites W2004343930 @default.
W1974872027 cites W2010809160 @default.
W1974872027 cites W2011482531 @default.
W1974872027 cites W2012566560 @default.
W1974872027 cites W2016472377 @default.
W1974872027 cites W2021442664 @default.
W1974872027 cites W2022329511 @default.
W1974872027 cites W2026862001 @default.
W1974872027 cites W2028259290 @default.
W1974872027 cites W2030433511 @default.
W1974872027 cites W2031277259 @default.
W1974872027 cites W2033744762 @default.
W1974872027 cites W2035786208 @default.
W1974872027 cites W2037616576 @default.
W1974872027 cites W2038707767 @default.
W1974872027 cites W2038858200 @default.
W1974872027 cites W2040340001 @default.
W1974872027 cites W2041147292 @default.
W1974872027 cites W2043466950 @default.
W1974872027 cites W2044625514 @default.
W1974872027 cites W2045743496 @default.
W1974872027 cites W2057147572 @default.
W1974872027 cites W2060967087 @default.
W1974872027 cites W2061711248 @default.
W1974872027 cites W2062426713 @default.
W1974872027 cites W2064223528 @default.
W1974872027 cites W2078300107 @default.
W1974872027 cites W2082461046 @default.
W1974872027 cites W2084332493 @default.
W1974872027 cites W2087320324 @default.
W1974872027 cites W2090212481 @default.
W1974872027 cites W2092508377 @default.
W1974872027 cites W2094110149 @default.
W1974872027 cites W2096682995 @default.
W1974872027 cites W2102238417 @default.
W1974872027 cites W2105942108 @default.
W1974872027 cites W2111566878 @default.
W1974872027 cites W2113840820 @default.
W1974872027 cites W2120955891 @default.
W1974872027 cites W2125184934 @default.
W1974872027 cites W2128847471 @default.
W1974872027 cites W2132286805 @default.
W1974872027 cites W2141511265 @default.
W1974872027 cites W2152550713 @default.
W1974872027 cites W2152948685 @default.
W1974872027 cites W2154452825 @default.
W1974872027 cites W2155311025 @default.
W1974872027 cites W2167345633 @default.
W1974872027 cites W2167782460 @default.
W1974872027 cites W2171968174 @default.
W1974872027 cites W2394635118 @default.
W1974872027 cites W2471397446 @default.
W1974872027 cites W3025856704 @default.
W1974872027 doi "https://doi.org/10.1016/j.chemgeo.2008.12.030" @default.
W1974872027 hasPublicationYear "2009" @default.
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