Microstructural characterization of inhomogeneity in 9Cr ODS EUROFER steel

Ferritic-martensitic ODS steels are one of the candidate materials for Gen-IV nuclear fission and fusion reactors. Residual ferrite was often found in the microstructure of 9Cr ODS steels. This constituent was reported to be responsible for the superior creep and high-temperature strength. Using opt...

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Bibliographic Details
Published in:Journal of nuclear materials 2020-05, Vol.533, p.152083, Article 152083
Main Authors: Das, A., Chekhonin, P., Altstadt, E., Bergner, F., Heintze, C., Lindau, R.
Format: Article
Language:English
Subjects:
Air temperature
Creep (materials)
Densification
Dislocation density
Dispersion hardening alloys
Dispersion hardening steels
Electron backscatter diffraction
Electron microscopy
Ferrites
Ferritic stainless steels
Ferritic-martensitic steel
Fusion reactors
Hardness
High temperature
Inhomogeneity
Iron constituents
Light microscopy
Martensitic stainless steels
Materials selection
Mechanical alloying
Mechanical properties
Microscopes
Microscopy
Microstructure
Nanoindentation
Nanoparticles
Nuclear fission
Nuclear fusion
Nuclear reactors
ODS steel
Optical microscopy
Residual ferrite
Scanning electron microscopy
Transmission electron microscopy
Yield
Yield strength
Yield stress
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Summary:Ferritic-martensitic ODS steels are one of the candidate materials for Gen-IV nuclear fission and fusion reactors. Residual ferrite was often found in the microstructure of 9Cr ODS steels. This constituent was reported to be responsible for the superior creep and high-temperature strength. Using optical microscopy of an air-cooled batch of ODS EUROFER, inhomogeneous regions in the microstructure have been found with similar appearance to previously reported residual ferrite. In order to avoid a potential misinterpretation of inhomogeneous regions as residual ferrite, detailed microstructural investigations have been carried out on the inhomogeneous regions using site-specific nanoindentation, scanning electron microscopy including electron backscatter diffraction, and transmission electron microscopy. It is demonstrated that the inhomogeneous regions are free of oxide nanoparticles, which possibly form due to imperfect mechanical alloying. These regions also exhibit lower hardness which is attributed to the absence of nanoparticles and a lower dislocation density. It is concluded that optical microscopy alone is insufficient to distinguish beneficial residual ferrite from undesired particle-free regions. Our findings are underpinned by the consistency between the calculated theoretical yield strength, the yield strength converted from the indentation hardness and the yield strength obtained from tensile testing. [Display omitted] •Inhomogeneous regions of ODS EUROFER were investigated using electron microscopy and site-specific nanoindentation.•Inhomogeneous regions are not residual ferrite as they exhibit lower hardness than the matrix and contain no nanoparticles.•The absence of nanoparticles and a lower dislocation density are mainly responsible for the lower hardness of these regions.•Optical microscopy alone is insufficient to identify inhomogeneous regions as being residual ferrite.•Reasonable consistency in the yield strength obtained from different methods is achieved.
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2020.152083