Metastability of the 10- Phase in the System MgO-SiO2-H2O (MSH). What about Hydrous MSH Phases in Subduction Zones?     

WUNDER  BERND; SCHREYER  WERNER 《Journal of Petrology》1992,33(4):877-889

The so-called 10- phase of the MgO-SiO₂-H₂O (MSH) system wassynthesized with 100% yields from a 3: 4 MgO/SiO₂ gel at fluidpressure of 50 kb and 500 C, but only during runs of up to1 h and with total H₂O contents near 50 wt. % in the sealedcapsules. The water contents determined in the run productsindicate a chemical composition Mg₃Si₄O₁₀(OH)₂0.65 H₂O, whichis different from the composition reported by Bauer & Sclar(1981), which had 1 H2O molecule per talc formula. The 10-phase has a = 5.293(3) , b = 9.194(3) , c = 10.044(3) , ß=96.10(8)its calculated density is p_calc.= 2.672 g/cm³; the refractiveindices measured are n_x = 1.554. and n_x = 1.574. The compatibilityof mean refractive index, calculated density, and chemical compositionfalls within the category ‘excellent’ of Mandarino(1979). Runs of longer durations and with total H₂O again near 50 wt.%, seeded with the less hydrous phase talc with the same Mg/Siratio, show that the 10- phase breaks down in the range 30–70kb, 200–700 C to form more talc. Thus it is not the stablehydrous high-pressure equivalent of talc as reported by Yamamoto& Akimoto (1977), but a metastable phase, which cannot playany role as a natural mineral of the mantle or of subductionzones. If the tie-line forsterite-H₂O is stable in the MSH system,as it seems to be for the conditions of our experiments, mostof the hydrous, silica-poor, new high-pressure MSH phases maybe without significance for the Earth, except perhaps phaseA with as yet an ambiguous composition.  相似文献   

An Experimental Study of Fe-Al Solubility in the System Corundum-Hematite up to 40 kbar and 1300{degrees}C     

FEENSTRA  A.; SAMANN  S.; WUNDER  B. 《Journal of Petrology》2005,46(9):1881-1892

The mutual solubility in the system corundum–hematite[-(Al, Fe³⁺)₂O₃] was investigated experimentally using bothsynthetic and natural materials. Mixtures of -Al₂O₃ and -Fe₂O₃(weight ratios of 8:2 and 10:1) were used as starting materialsfor synthesis experiments in air at 800–1300°C withrun times of 7–34 days. Experiments at 8–40 kbarand 490–1100°C were performed in a piston-cylinderapparatus (run times of 0·8–7·4 days) usinga natural diasporite consisting of 60–70 vol. % diasporeand 20–30 vol. % Ti-hematite. During the diasporite–corunditetransformation, the FeTiO₃ component (12–18 mol %) ofTi-hematite only slightly increased, implying that oxygen fugacitywas maintained at high values. Run products were studied byelectron microprobe and X-ray diffraction (Rietveld) techniques.An essentially linear volume of mixing exists in the solid solutionwith a slight positive deviation at the hematite side. Up to1000°C, corundum contains <4 mol % Fe₂O₃ and hematite<10 mol % Al₂O₃; at 1200°C these amounts increase to9·3 and 17·0 mol %, respectively. At 1300°Chematite was no longer stable and coexists with the orthorhombic phase . The present results agree with corundum (solvus) compositions obtained inprevious studies but indicate a larger solubility of Al in hematite.The miscibility gap in the solution can be modelled with anasymmetric Margules equation with interaction parameters (2uncertainties): ; ; ; . Application of the corundum–hematite solution as a solvus geothermometer is limited because of thescarcity of suitable rock compositions. KEY WORDS: corundum; hematite; corundum–hematite miscibility gap; experimental study; Margules model; metabauxite  相似文献