2000
DOI: 10.1007/s004100000174
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Kankan diamonds (Guinea) II: lower mantle inclusion parageneses

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Cited by 257 publications
(136 citation statements)
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“…In fact, there has been a growing body of evidence for the ultradeep subduction of carbonates and their participation in the formation of diamonds. This evidence involves the discovery of inclusions in diamonds, consisting of carbonates in association with the superdeep phases CaSiO 3 or MgO + MgSiO 3 , as well as some experimental and geochemical observations (51)(52)(53)(54). Our results suggest that the Ca-rich carbonate melt, which forms through the carbonate-iron interaction and can be generated even in the absence of alkalis and H 2 O, can be considered as a transmantle interstitial melt.…”
Section: Significancesupporting
confidence: 51%
“…In fact, there has been a growing body of evidence for the ultradeep subduction of carbonates and their participation in the formation of diamonds. This evidence involves the discovery of inclusions in diamonds, consisting of carbonates in association with the superdeep phases CaSiO 3 or MgO + MgSiO 3 , as well as some experimental and geochemical observations (51)(52)(53)(54). Our results suggest that the Ca-rich carbonate melt, which forms through the carbonate-iron interaction and can be generated even in the absence of alkalis and H 2 O, can be considered as a transmantle interstitial melt.…”
Section: Significancesupporting
confidence: 51%
“…However, as observed in the upper mantle, heterogeneities of the lower mantle redox state probably exist: For instance, subduction zones are made of more oxidized materials (10) that could survive on long time scales. Coexistence of both reduced and oxidized species in the deep Earth is also suggested by examples such as CO 2 -rich kimberlitic magmas that have transported diamonds to the surface (11,12), and some carbonate inclusions that were found in diamonds from the lower mantle (13,14). Results of high-pressure experiments on carbonate stability suggest that the rhombohedral structure of MgCO 3 magnesite is stable up to 115 GPa at 2,000-3,000 K, but that it adopts a new structure at higher pressures (8).…”
mentioning
confidence: 81%
“…It was the discovery of diamonds containing coexisting, but nontouching, inclusions of ferropericlase, MgSiO 3 and CaSiO 3 (Harte et al 1999) that provided convincing evidence that some diamonds are exhumed from the lower mantle. As with majorite-bearing samples, the number of possible lower mantle diamond occurrences has grown since the initial discoveries, and examples are now recognised in South Africa (Moore et al 1986), Guinea (Stachel et al 2000b(Stachel et al , 2002, Canada (Davies et al 2004;Tappert et al 2005), Australia (Tappert et al 2009a, b) and Brazil, both from Machado river ) and the Juina region (see below). However, in contrast to majorite-bearing diamonds, the number of definitively lower mantle diamonds remains small and most of the diamonds are associated with peridotitic material (Harte 2010;Kaminsky 2012).…”
Section: Introductionmentioning
confidence: 99%