Peritectic Reaction of Olivine in the Carbonate–Silicate–(C–O–H) Diamond-Forming System at 6 GPa

IF 0.7 4区地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Geochemistry International Pub Date : 2024-04-01 DOI:10.1134/S001670292401004X

A. V. Kuzyura, A. V. Spivak, Yu. A. Litvin

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Abstract

The influence of the components of supercritical C–O–H fluid (at a content of 7.5 wt %) on the melting relations in the multicomponent diamond-forming system olivine–jadeite–diopside–(Mg–Fe–Ca–Na carbonates)–(C–O–H) was studied experimentally at 6 GPa and 700–1200°C under the conditions of the upper mantle. The peritectic reaction of olivine and jadeite-bearing melt with the formation of garnet was suggested as a key mechanism for the ultramafic–mafic evolution of diamond-forming melts. The CO₂ component of the C–O–H fluid reacts with silicate components to form carbonates. The H₂O component, together with carbonate compounds of the diamond-forming system, reduces the temperature of its liquidus and solidus boundaries significantly. After the completion of crystallization of a completely miscible silicate–carbonate–(C–O–H fluid) melt, a phase of supercritical aqueous fluid and hydrous carbonate nesquehonite MgCO₃·3H₂O identified by Raman spectroscopy appear in the subsolidus of the diamond-forming system.

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6 GPa 下碳酸盐-硅酸盐-(C-O-H) 金刚石形成体系中的橄榄石围岩反应

在 6 GPa 和 700-1200°C 的上地幔条件下，实验研究了超临界 C-O-H 流体成分（含量为 7.5 wt %）对多组分金刚石形成体系橄榄石-翡翠-透辉石-（镁-铁-钙-钠碳酸盐）-（C-O-H）熔融关系的影响。橄榄石和含翡翠熔体的包晶反应与石榴石的形成被认为是金刚石形成熔体的超基性黑云母演化的关键机制。C-O-H流体中的CO2成分与硅酸盐成分反应形成碳酸盐。H2O 成分与金刚石形成体系的碳酸盐化合物一起，大大降低了其液界和固界的温度。在完全混溶的硅酸盐-碳酸盐-（C-O-H 流体）熔体结晶完成后，金刚石形成体系的次固相中出现了超临界水相流体和通过拉曼光谱鉴定的含水碳酸盐内斜碳酸盐 MgCO3-3H2O。

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来源期刊

Geochemistry International 地学-地球化学与地球物理

CiteScore

1.60

自引率

12.50%

发文量

审稿时长

1 months

期刊介绍： Geochemistry International is a peer reviewed journal that publishes articles on cosmochemistry; geochemistry of magmatic, metamorphic, hydrothermal, and sedimentary processes; isotope geochemistry; organic geochemistry; applied geochemistry; and chemistry of the environment. Geochemistry International provides readers with a unique opportunity to refine their understanding of the geology of the vast territory of the Eurasian continent. The journal welcomes manuscripts from all countries in the English or Russian language.