论文信息 - Phase stability of oxide dispersion-strengthened ferritic steels in neutron irradiation

Phase stability of oxide dispersion-strengthened ferritic steels in neutron irradiation

Abstract Oxide dispersion-strengthened ferritic steels were irradiated by neutrons up to 21 dpa and studied by microstructural observation and microchemical analysis. The original high dislocation density did not change after neutron irradiation, indicating that the dispersed oxide particles have high stability under neutron irradiation. However, there is potential for recoil resolution of the oxide particles due to ballistic ejection at high dose. From the microchemical analysis, it was implied that some of the complex oxides have a double-layer structure, such that TiO2 occupied the core region and Y2O3 the outer layer. Such a structure may be more stable than the simple mono-oxides. Under high-temperature irradiation, Laves phase was the predominant precipitate occurring at grain boundaries α phase and χ phase were not observed in this study.

[1] A. Kohyama,et al. Microstructural evolution of an oxide dispersion strengthened steel under charged particle irradiation , 1988 .

[2] R. Roth,et al. Low-Temperature Phase Relationships in the System ZrO2-TiO2 , 1986 .

[3] H. S. Parker,et al. Synthesis, Stability, and Crystal Chemistry of Dibarium Pentatitanate , 1986 .

[4] E. Little,et al. Effects of ion irradiation on the microstructure of an oxide-dispersion-strengthened ferritic steel , 1991 .

[5] Seiichi Watanabe,et al. Effect of mechanical alloying parameters on irradiation damage in oxide dispersion strengthened ferritic steels , 2000 .

[6] N. Akasaka,et al. Void formation and microstructural development in oxide dispersion strengthened ferritic steels during electron-irradiation , 1998 .

[7] M. Harada,et al. Tube manufacturing and mechanical properties of oxide dispersion strengthened ferritic steel , 1993 .

[8] T. Okuda,et al. Dispersion behaviour of oxide particles in mechanically alloyed ODS steel , 1995 .

[9] T. Kondo,et al. Phase stability of reduced activation ferritic steel: 8%Cr-2%W-0.2%V-0.04%Ta-Fe , 1988 .

[10] M. Inoue,et al. Effects of Grain Morphology and Texture on High Temperature Deformation in Oxide Dispersion Strengthened Ferritic Steels , 1996 .

[11] M. Harada,et al. Alloying design of oxide dispersion strengthened ferritic steel for long life FBRs core materials , 1993 .