The system k2co3–caco3 at 3 gpa: link between phase relations and variety of k–ca double carbonates at ≤ 0.1 and 6�gpa

Arefiev A.V.; Shatskiy A.; Podborodnikov I.V.; Rashchenko S.V.; Chanyshev A.D.; Litasov K.D.

doi:10.1007/s00269-018-1000-z

Инд. авторы:	Arefiev A.V., Shatskiy A., Podborodnikov I.V., Rashchenko S.V., Chanyshev A.D., Litasov K.D.
Заглавие:	The system k₂co₃–caco₃ at 3 gpa: link between phase relations and variety of k–ca double carbonates at ≤ 0.1 and 6 gpa
Библ. ссылка:	Arefiev A.V., Shatskiy A., Podborodnikov I.V., Rashchenko S.V., Chanyshev A.D., Litasov K.D. The system k₂co₃–caco₃ at 3 gpa: link between phase relations and variety of k–ca double carbonates at ≤ 0.1 and 6 gpa // Physics and Chemistry of Minerals. - 2019. - Vol.46. - Iss. 3. - P.229-244. - ISSN 0342-1791. - EISSN 1432-2021.
Внешние системы:	DOI: 10.1007/s00269-018-1000-z; РИНЦ: 35748533; SCOPUS: 2-s2.0-85053637063; WoS: 000463607600003;
Реферат:	eng: The K₂CO₃–CaCO₃ system is important both in materials science as a source of new nonlinear optical materials and in the Earth science as a sub-system modeling phase relations in fluxing component of mantle rocks responsible for the generation of deep-seated magmas. Existing data on phase relations in the K₂CO₃–CaCO₃ system at ≤ 0.1 and 6 GPa show significant difference in intermediate compounds and, therefore, do not allow any interpolation between these pressures. Here, we report experimental results on melting and subsolidus phase relations in the system K₂CO₃–CaCO₃ at 3 GPa and 800–1285 °C. At 800 °C, the system has two intermediate compounds: K₂Ca(CO₃)₂, synthetic analog of mineral buetschliite, and K₂Ca₂(CO₃)₃. As temperature increases to 850 °C, a third intermediate compound, K₂Ca₃(CO₃)₄, appears. The calcite–aragonite transition boundary is located at 962 ± 12 °C. Maximum solid solution of CaCO₃ in K₂CO₃ is 18 mol% at 950 °C. The K carbonate–K₂Ca(CO₃)₂ eutectic is established near 970 °C and 56 mol% K₂CO₃. The melting point of K₂CO₃ corresponds to 1275 ± 25 °C. K₂Ca(CO₃)₂ melts incongruently at 988 ± 12 °C to produce K₂Ca₂(CO₃)₃ and a liquid containing 53 mol% K₂CO₃. K₂Ca₂(CO₃)₃ melts congruently just above 1100 °C. The K₂Ca₂(CO₃)₃–K₂Ca₃(CO₃)₄ eutectic is situated near 1085 °C and 29 mol% K₂CO₃. K₂Ca₃(CO₃)₄ melts incongruently at 1100 °C to produce calcite and a liquid containing 28 mol% K₂CO₃. Considering our present results and previous data on the K₂CO₃–CaCO₃ system, a range of K-Ca double carbonates changes upon pressure and temperature increase in the following sequence: K₂Ca(CO₃)₂ (buetschliite), K₂Ca₂(CO₃)₃ (≤ 0.1 GPa; < 547 °C) → K₂Ca(CO₃)₂ (fairchildite), K₂Ca₂(CO₃)₃ (≤ 0.1 GPa; 547–835 °C) → K₂Ca(CO₃)₂ (buetschliite), K₂Ca₂(CO₃)₃, K₂Ca₃(CO₃)₄ (ordered) (3 GPa; 800–1100 °C) → K₈Ca₃(CO₃)₇, K₂Ca(CO₃)₂ (buetschliite), K₂Ca₃(CO₃)₄ (disordered) (6 GPa; 900–1300 °C).
Ключевые слова:	FAIRCHILDITE; ALKALI; MANTLE; PRESSURE; FUSION CURVE; POTASSIUM CARBONATE; CRYSTAL-STRUCTURE; CACO3; Raman; Fairchildite; Buetschliite; K-Ca carbonates; High-pressure; Phase relations; K2CO3;
Издано:	2019
Физ. характеристика:	с.229-244
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