Molecular dynamics simulations of cascade damage near the Y2Ti2O7 nanocluster/ferrite interface in nanostructured ferritic alloys

A comparative study of cascades in nanostructured ferritic alloys and pure Fe is performed to reveal the influence of Y_2Ti_2O_7 nanocluster on cascades by molecular dynamics simulations. The cascades with energies of primary knock-on atom(PKA) ranging from 0.5 keV to 4.0 keV and PKA's distances to...

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Published in中国物理B:英文版 Vol. 26; no. 7; pp. 287 - 293
Main Author 孙祎强 赖文生
Format Journal Article
LanguageEnglish
Published 01.07.2017
Subjects
分子动力学模拟
损伤
界面
级联扩展
纳米团簇
结构
铁氧体
铁素体合金
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ISSN1674-1056
2058-3834
DOI10.1088/1674-1056/26/7/076106

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Summary:A comparative study of cascades in nanostructured ferritic alloys and pure Fe is performed to reveal the influence of Y_2Ti_2O_7 nanocluster on cascades by molecular dynamics simulations. The cascades with energies of primary knock-on atom(PKA) ranging from 0.5 keV to 4.0 keV and PKA's distances to the interface from 0  to 50  are simulated. It turns out that the Y_2Ti_2O_7 nanocluster can absorb the kinetic energy of cascade atoms, prevent the cascade from extending and reduce the defect production significantly when the cascades overlap with the nanocluster. When the cascade affects seriously the nanocluster, the weak sub-cascade collisions are rebounded by the nanocluster and thus leave more interstitials in the matrix. On the contrary, when the cascade contacts weakly the nanocluster, the interface can pin the arrived interstitials and this leaves more vacancies in the matrix. Moreover, the results indicate that the Y_2Ti_2O_7 nanocluster keeps stable upon the displacement cascade damage.
Bibliography:A comparative study of cascades in nanostructured ferritic alloys and pure Fe is performed to reveal the influence of Y_2Ti_2O_7 nanocluster on cascades by molecular dynamics simulations. The cascades with energies of primary knock-on atom(PKA) ranging from 0.5 keV to 4.0 keV and PKA's distances to the interface from 0  to 50  are simulated. It turns out that the Y_2Ti_2O_7 nanocluster can absorb the kinetic energy of cascade atoms, prevent the cascade from extending and reduce the defect production significantly when the cascades overlap with the nanocluster. When the cascade affects seriously the nanocluster, the weak sub-cascade collisions are rebounded by the nanocluster and thus leave more interstitials in the matrix. On the contrary, when the cascade contacts weakly the nanocluster, the interface can pin the arrived interstitials and this leaves more vacancies in the matrix. Moreover, the results indicate that the Y_2Ti_2O_7 nanocluster keeps stable upon the displacement cascade damage.
Yi-Qiang Sun,Wen-Sheng Lai( Laboratory of Advanced Materials, School of Materials Science and Engineering, Tsinghua University, Beijing 100084, China)
nanostructured ferritic alloys; molecular dynamics simulation; Y2Ti2O7; displacement cascade
11-5639/O4
ISSN:1674-1056
2058-3834
DOI:10.1088/1674-1056/26/7/076106