Effects of Alloying Elements on the Solution and Diffusion of Oxygen at Iron Grain Boundary Investigated by First-Principles Study

The effects of alloying elements (Si, Cr, Mo) on the solution and diffusion of oxygen (O) atoms at the grain boundary of iron (Fe) Σ5(310)/[001] are investigated by the simulations of ab initio density functional theory (DFT). It is found that Si, Mo and Cr prefer to segregate to the grain boundary,...

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Published inMetals (Basel ) Vol. 13; no. 4; p. 789
Main Authors Zhang, Jingdan, Li, Xiaolin, Lei, Yawei, Zhang, Yange, Li, Xiangyan, Xu, Yichun, Wu, Xuebang, Yang, Junfeng, Li, Bingsheng, Liu, Changsong
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.04.2023
Subjects
Alloying effects
Alloying elements
Atomic interactions
Boundary conditions
Charge transfer
Chromium
Corrosion resistance
Density functional theory
Density functionals
Diffusion
Energy
First principles
first-principles calculation
Grain boundaries
Grain size
Heat conductivity
Investigations
Iron
Iron alloys
iron grain boundary
Molybdenum
Nuclear reactors
Oxidation
oxidation corrosion
Oxygen
Silicon
solution and diffusion
Specialty metals industry
Steel
Germany
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Summary:The effects of alloying elements (Si, Cr, Mo) on the solution and diffusion of oxygen (O) atoms at the grain boundary of iron (Fe) Σ5(310)/[001] are investigated by the simulations of ab initio density functional theory (DFT). It is found that Si, Mo and Cr prefer to segregate to the grain boundary, and further affect the solution and diffusion of O atoms at Fe grain boundaries. The segregated Cr promotes the solution of O, while Si and Mo inhibit the solution of O at the grain boundary. Meanwhile, Cr and Si accelerate the diffusion of O, and Mo retards the diffusion of O in the grain boundary. Further analysis indicates that the effects are closely related to the interactions between the alloying elements and O atoms, which are determined by the competition between the distortion of local structure and the charge transfer between local atoms. Finally, the effects of alloying elements on the O concentration distribution near the grain boundary are explored by employing the Langmuir–McLean models. This work not only provides insights into the effects of alloying elements on the solution and diffusion of O at grain boundaries, but also provides parameters of the atomic interactions for the initial oxidation simulation on a large scale, which relates to the growth of oxide in polycrystalline systems with various grain sizes at experimental temperatures.
ISSN:2075-4701
2075-4701
DOI:10.3390/met13040789