Evolution of the oxide structure of 9CrODS steel exposed to supercritical water

The corrosion behavior and oxide structure of 9CrODS steel in supercritical water has been studied. Samples were exposed to supercritical water at 500 and 600 °C for times of 2, 4 and 6 weeks. The oxide structure was studied using microbeam synchrotron X-ray diffraction and fluorescence analysis. The 600 °C samples exhibited a three-layer structure with Fe 3O 4 in the outer layer, a mixture of FeCr 2O 4 and Fe 3O 4 in the inner layer, and a mixture of metal and oxide grains (FeCr 2O 4 and Cr 2O 3) in the diffusion layer. Between the 2 and 4-week samples exposed to 600 °C supercritical water, a Cr 2O 3 film appeared at the diffusion layer–metal interface which appears to be associated with slower oxidation of the metal. The 500 °C samples also showed a three-layer structure, but both the outer and inner oxide layers contained mainly Fe 3O 4, and the diffusion layer contained much fewer oxide precipitates and was a solid solution of oxygen ahead of the oxide front.