Effect of stress state on graphitization behavior of diamond under high pressure and high temperature

Pure diamond powder and mixed powder of diamond and sodium chloride were treated at high pressures (5 GPa and 10 GPa) and high temperatures (1000-2700 ?), and then the graphitization behavior of diamond powder under non-hydrostatic (pure diamond powder) and quasi-hydrostatic (mixed powder of diamond and sodium chloride) compression was quantitatively studied by analyzing the X-ray diffraction peaks' area of treated samples. It is found that the graphitization under non-hydrostatic compression is much more easily triggered by heating due to the heterogeneous stress distribution within the diamond grains. Under the quasi-hydrostatic compression of 5 GPa, the starting graphitization temperature is about 1600 ?, which is 300 ?higher than that under non-hydrostatic compression. Under a pressure of 10 GPa, graphitization could be observed after pure diamond powder was treated at 1400 ?, but no graphitization occurred in the mixed powder even after a high temperature treatment at 2300 & DEG;C. Optimizing the stress distribution among diamond grains by the mixing of grain-size can significantly reduce the graphitization at high temperature even under non-hydrostatic compression.

Automated summary

The graphitization behavior of diamond particles under high pressure and high temperature conditions was studied. It was found that diamond particles were more prone to graphitization under non-hydrostatic compression when heated, and mixing the particle sizes could significantly reduce graphitization.