The reaction between potassium feldspar (Kfs) and dolomite (Dol) could define the solidus of carbonated pelite below 7 GPa under nominally anhydrous conditions (Grassi and Schmidt, 2011). To investigate this reaction subsolidus and melting phase relations in the systems KAlSi₃O₈ + CaMg(CO₃)₂ (Kfs + Dol), KAlSi₃O₈ + CaMgSi₂O₆ + NaAlSi₂O₆ + CaMg(CO₃)₂ (Kfs + Di + Jd + Dol), and KAlSi₃O₈ + Na₂CO₃ + CaMg(CO₃)₂ (Kfs + Na₂ + Dol) have been examined at 6 GPa and compared with those established in dry carbonated pelite (DG2).
In the system Kfs+Dol at 1000 °C, the subsolidus assemblage consists of Kfs and Dol. Besides, Kfs contains numerous inclusions of K₂Si₄O₉ wadeite (K-wad), kyanite (Ky), coesite (Coe). At lower temperature 900 °C, Kfs and Dol are not stable and the assemblage includes K-wad, Ky, Coe, aragonite (Arg) and magnesite (Mgs). The system begins to melt at 1100 °C via reaction 6KAlSi₃O₈ (Kfs) + 6CaMg(CO₃)₂ (Dol) = 2(Ca_n,Mg_1-n)₃Al₂Si₃O₁₂ (Grt) + Al₂SiO₅ (Ky) + 11SiO₂ (Coe) + 3K₂(Ca_1-n,Mg_n)₂(CO₃)₃ (L) + 3CO₂ (F and/or L), where n ~ 0.3-0.4, leading to essentially carbonate liquid, L(C), with composition of 32K₂CO₃·68(Ca_0.63Mg_0.37)CO₃ + 1-2 mol% SiO₂ + 0.5-1 mol% Al₂O₃. Kfs and Dol completely disappear at 1150 °C. Starting from 1300 °C, immiscible silicate melt, L(S), coexists with L(C). L(S) contains (in mol%): 64 SiO₂, 9 Al₂O₃, 2 MgO, 2 CaO, 11 K₂O, and 12 CO₂. The Grt + Coe + Ky + L(C) + L(S) phase assemblage remains stable up to 1500 °C.
Adding Di-Jd clinopyroxene in the Kfs + Dol system does not affect phase relations. At 1000 °C, the subsolidus assemblage is Kfs + CPx + Dol. Kfs is partially replaced by K-wad + Ky + Coe assemblage. Above the solidus at 1150 °C, Cpx, Grt, Ky, Coe coexist with L(C) [34(K_0.92Na_0.08)₂CO₃·66(Ca_0.62Mg_0.38)CO₃ + 3 mol% SiO₂ + 1 mol% Al₂O₃]. L(S) appears at 1250 °C and contains (in mol%): 67 SiO₂, 7 Al₂O₃, 4 MgO, 4 CaO, 1 Na₂O, 7 K₂O, and 10 CO₂. The Cpx + Grt + Ky + Coe + L(C) + L(S) phase assemblage was established at 1250 and 1350 °C, whereas at 1500 °C only CPx remains in coexistence with L(C) and L(S).
At 900 °C in the Kfs + Na₂ + Dol system, the subsolidus assemblage consists of Cpx (Jd_87-90Di_10-13), (Na_0.55K_0.45)₂Mg_0.90Ca_0.10(CO₃)₂ (NaKMg), (Na_0.63K_0.37)₂(Ca_0.93Mg_0.07)₃(CO₃)₄ (NaKCa₃), Coe, and Mgs. As temperature increases to 1000 °C, NaKMg and NaKCa₃ disappear, while minor amount of Mgs and Coe remains. The sample consists of Cpx (Jd₇₈Di₂₂) and L(C) [44(Na_0.51K_0.49)₂CO₃·56Ca_0.57Mg_0.43CO₃]. Thus, an addition of Na₂CO₃ into the Kfs+Dol system yields formation of Cpx, NaKMg and NaKCa₃ at the expense of K-wad, Ky, Mgs, and Arg. Molar abundances of phases and their compositions change slightly with further temperature increase up to 1500 °C. Thus, Na₂CO₃ causes redistribution of K₂O into carbonate phases, whereas SiO₂ and Al₂O₃ are consumed on jadeite formation: Na₂CO₃ + KAlSi₃O₈ (Kfs or L(S)) = NaAlSi₂O₆ + SiO₂ + NaKCO₃ (L(C)). As a result, immiscible L(S) does not appear in this system.
In dry carbonated pelite (DG2), subsolidus assemblage established at 1000 °C is represented by Cpx, Grt, Ky, Coe, Dol, and K₂Ti_1-nSi_3+nO₉ wadeite. Two immissible liquids were established at 1350 and 1500 °C in coexistence with Cpx, Coe, Grt, Ky and CO₂ fluid. At 1350 °C, L(S) contains (in mol%): 56.6 SiO₂, 1.8 TiO₂, 8.3 Al₂O₃, 2.9 FeO, 1.3 MgO, 3.2 CaO, 1.4 Na₂O, 9.7 K₂O, and 15.0 CO₂, whereas L(C) composition is (K_0.74Na_0.26)₂(Ca_0.58Mg_0.18Fe_0.24)₄CO₃ + 4.2 mol% SiO₂ + 1.7 mol% TiO₂ + 1.4 mol% Al₂O₃.
The obtained immissible L(C) and L(S) resemble compositions of melt inclusions in fibrous diamonds worldwide. Thus, the K-aluminosilicate and K-Na-rich carbonatite melts entrapped by fibrous diamonds could be derived by liquid immissibility during partial melting of carbonated pelite subducted down to 180 km depth and heated to 1300 °C or higher temperature.
This work is financially supported by Russian Science Foundation (No 14-17-00609).