Investigation of instability of M^sub 23^C^sub 6^ particles in F82H steel under electron and ion irradiation conditions

In order to clarify the instability of M23C6 in F82H steel under irradiation, both electron irradiation using a high voltage electron microscope (HVEM) and ion irradiation using an ion accelerator were performed. For the electron irradiation, in-situ observation under 2 MV electron irradiation and e...

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Bibliographic Details
Published inJournal of nuclear materials Vol. 502; p. 263
Main Authors Kano, Sho, Yang, Huilong, Shen, Jingjie, Zhao, Zishou, McGrady, John, Hamaguchi, Dai, Ando, Mamami, Tanigawa, Hiroyasu, Abe, Hiroaki
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier BV 15.04.2018
Subjects
Carbides
Coarsening
Constituents
Crystal defects
Cyclotrons
Diffusion
Dissolution
Electron beams
Electron irradiation
Electrons
Enhanced diffusion
Flow rates
Flow velocity
High voltage
High voltages
Ion irradiation
Ions
Iron
Irradiation
Lattice vacancies
Particulates
Precipitates
Shrinkage
Stability
Steel
Temperature dependence
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Summary:In order to clarify the instability of M23C6 in F82H steel under irradiation, both electron irradiation using a high voltage electron microscope (HVEM) and ion irradiation using an ion accelerator were performed. For the electron irradiation, in-situ observation under 2 MV electron irradiation and ex-situ high resolution electron microscopic (HREM) analysis were utilized to evaluate the response of M23C6 against irradiation. The temperature dependence of the irradiation induced instability of the carbide was first confirmed: 293 K < T < 573 K, by observation of lowering in contrast at the periphery of carbides, 698 K < T < 773 K, fragmentation at the interface between carbides and matrix, and at 773 K, formation and coarsening of new particles near the periphery of M23C6. HREM analysis showed the loss of the lattice fringe contrast at the pre-existing M23C6 precipitates at temperatures ranging from 473 to 773 K, indicating severe loss of crystallinity due to dissolution of the constituent atoms though irradiation-enhanced diffusion under the vacancy diffusion by the focused electron beam irradiation. For the ion irradiation, 10.5 MeV-Fe3+ ion was applied to bombard the F82H steel at 673 K to achieve the displacement damage of ≈20 dpa at the depth of 1.0 μm from surface. Cross-section TEM specimens were prepared by a focused ion beam technique. The shrinkage of carbide particles was observed especially near the irradiation surface. Besides, the lattice fringes at the periphery of carbide were observed in the irradiated M23C6 by the HREM analysis, which is different from that observed in the electron irradiation. It was clarified that the instability of M23C6 is dependent on the irradiation conditions, indicating that the flow rate of vacancy type defects might be the key factor to cause the dissolution of constituent atoms of carbide particles into matrix under irradiation.
ISSN:0022-3115
1873-4820