PHASE FORMATION AND DIAMOND CRYSTALLIZATION IN CARBON-BEARING ULTRAPOTASSIC CARBONATE-SILICATE SYSTEMS

Diamond crystallization and character of phase formation in the systems K₂CO₃–C, K₂CO₃–SiO₂–C, and K₂CO₃–Mg₂SiO₄–C were studied at 6.3 GPa and 1650 °C for 40 hours using the multianvil split-sphere equipment. The SiO₂/K₂CO₃ and Mg₂SiO₄/K₂CO₃ ratios were chosen as variable parameters. The degree of graphite-to-diamond transformation and rate of diamond growth on seeds have been determined as a function of these ratios. Composition domains have been revealed in which spontaneous diamond nucleation and seeded growth occur. As the concentrations of silica and forsterite in the systems K₂CO₃–SiO₂–C and K₂CO₃–Mg₂SiO₄–C, respectively, increase to 10 wt.%, the diamond formation becomes more intense. Given a further increase in contents of SiO₂ or Mg₂SiO₄, this intensity gradually decreases until the complete termination of spontaneous nucleation and seeded diamond growth. The conditions were created under which diamond was crystallized from a potassium carbonate-silicate melt, including the main components of mantle-derived ultrapotassic fluxes, together with coesite in the system K₂CO₃–SiO₂–C and with forsterite in the system K₂CO₃–Mg₂SiO₄–C.