Radiation-induced swelling and radiation-induced segregation & precipitation in dual beam irradiated Ferritic/Martensitic HT9 steel

Abstract

Ferritic/Martensitic HT9 steel was irradiated at 432°C to 16.6 displacements per atom (dpa) (at the depth of 600nm) using a defocused beam of 5MeV Fe++ ions, while co-implanted with 3.22appm He at the same depth. The helium concentration profile was designed so to follow the damage curve with a 0.22appmHe/dpa ratio at the depth from 300 to 1000nm in the material. The depth-dependence of the cavity size and number density were characterized by both transmission electron microscopy (TEM) and scanning transmission electron microscopy (STEM) imaging methods. A comparison between the two techniques was done showing good agreement. Cavity number density and the resulting swelling were found to be suppressed by the injected interstitial effect in the vicinity of the ion induced damage peak. The region between 300 and 750nm depth which excludes the injected interstitial effect was thus proposed for improved cavity swelling analysis. The swelling ratio in this region was found to be ~(0.86–1.02)×10−2%/dpa. In addition, ChemiSTEM characterization revealed radiation-induced segregation occurring throughout the irradiated region and precipitation of G-phase particles. Segregation of Ni to cavity surfaces was also observed and its possible synergistic influence on swelling was discussed.