@article{oai:repo.qst.go.jp:00084572,
 author = {Kano, Sho and Yang, Huilong and McGrady, John and Watanabe, Yoshiyuki and Ando, Masami and Hamaguchi, Dai and Nozawa, Takashi and Tanigawa, Hiroyasu and Yoshida, Kenta and Shibayama, Tamaki and Abe, Hiroaki and Yoshiyuki, Watanabe and Masami, Ando and Dai, Hamaguchi and Takashi, Nozawa and Hiroyasu, Tanigawa},
 journal = {Journal of Nuclear Materials},
 month = {Oct},
 note = {The purpose of the present study is to clarify the instability behavior of M23C6 under irradiation, specifically the occurrence of radiation-induced amorphization (RIA). Ion irradiation of 10.5 MeV-Fe3+ at elevated temperatures from 573-623 K was conducted into the reduced activation ferritic/martensitic steels (F82H) and its model alloy (Fe-8Cr-0.1C). A bilayer contrast of the particle consisting of an amorphous-rim phase and inner crystalline core of M23C6 was observed in the irradiated F82H specimen, but not in the model alloy. From the high-resolution electron microscope observation, the preferential occupation site of W into M23C6 lattice was identified as 8c-site prior to irradiation in F82H specimen, which shifted to other sites due to chemical disordering upon irradiation. Evaluation of the intensity ratio between 8c and another site of M23C6, 8c/4a, then revealed that the extent of chemical disordering of W was mitigated at the amorphous-crystal interface region in comparison with the central of the particle. The hypothesis for the formation mechanism of an amorphous-rim in M23C6 was presumed as the deviation from the stoichiometric composition at the local interface due to the irradiation-enhanced diffusion and/or ballistic mixing under the current circumstances, although the efforts from experimental and/or simulation studies are still necessary to achieve a further understanding of the RIA behavior in M23C6.},
 title = {Radiation-Induced Amorphization of M23C6 in F82H steel: An atomic-scale Observation},
 volume = {558},
 year = {2021}
}