Effect of Oxygen on Diamond Crystallization in Metal-Carbon Systems

In this article, we report the influence of oxygen concentration in the transition-metal solvent-catalyst on the crystallization processes, morphology, and defect-and-impurity content of diamond crystals. In a series of experiments, the concentration of oxygen (C-o) in the growth system was varied by adding Fe2O3 to the charge, and the other parameters and conditions of the growth were constant: Ni7Fe3 solvent-catalyst, P = 6.0 GPa, T = 1400 degrees C, and duration of 40 h. It is found that on increasing C-o in the growth system from 0 to 10 wt %, the crystallization of diamond proceeds through the following stages: single crystal -> block crystal -> spontaneous crystals -> aggregate of block crystals and twin crystals. At C-o >= S wt %, diamond crystallizes jointly with wustite (FeO) and metastable graphite. The oxygen solubility in the iron-nickel melt is estimated at about 2 wt %. With increasing oxygen content in the system, the range of nitrogen concentrations in diamonds crystallized in one experiment significantly broadens with the maximum nitrogen concentrations being increased from 200-250 ppm in the experiment without O additives to 1100-1200 ppm in the experiment with 10 wt % O added. The established joint growth of diamond and wustite suggests possible crystallization of natural diamonds in the Fe-Ni-O-C system over a wide range of oxygen concentrations up to 10 wt %.