Microstructure and phase investigation of FeCrAl-Y2O3 ODS steels with different Ti and V contents

•FeCrAl-Y2O3 ODS alloys were fabricated for applications in GenIV nuclear reactors.•The mechanically alloyed powders show good chemical homogeneity.•The spark plasma sintered samples reveal good densification and bcc phase matrix.•Nanometric reinforcing particles (15–50 nm) are homogeneously distrib...

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Published inJournal of nuclear materials Vol. 586; p. 154700
Main Authors Jasinski, Jaroslaw J., Stasiak, Tomasz, Chmurzynski, Wojciech, Kurpaska, Lukasz, Chmielewski, Marcin, Frelek-Kozak, Malgorzata, Wilczopolska, Magdalena, Mulewska, Katarzyna, Zielinski, Maciej, Kowal, Marcin, Diduszko, Ryszard, Chrominski, Witold, Jagielski, Jacek
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.12.2023
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Summary:•FeCrAl-Y2O3 ODS alloys were fabricated for applications in GenIV nuclear reactors.•The mechanically alloyed powders show good chemical homogeneity.•The spark plasma sintered samples reveal good densification and bcc phase matrix.•Nanometric reinforcing particles (15–50 nm) are homogeneously distributed.•The alloy with the addition of vanadium shows improved mechanical properties. FeCrAl-based steels are considered promising materials for high-temperature nuclear applications. Over the past years, various compositions have been studied to assess their mechanical properties, structural integrity, and radiation damage resistance. However, the microstructure and phase composition of FeCrAl-ODS steels with the addition of different alloying elements are less commonly studied than pure FeCrAl alloys. The paper presents a novel research path for developing FeCrAl matrix ODS steels with Y2O3, Ti, and V additions. The materials synthesis consisted of mechanical alloying of pure metallic components with yttrium oxide in a planetary ball mill under an argon atmosphere. Titanium was added in the amount of 1.0 wt.% to both samples, while 0.5 wt.% of vanadium was added to one sample to verify its impact on the structural stability and hardness. The spark plasma sintering (SPS) technique was used to consolidate the powders. Afterward, the microstructure, chemical composition, phase composition, and hardness were assessed using SEM-EDS, EBSD, TEM-EDS, XRD, XRF, Nanoindentation, and Vickers microhardness. The experimental data reveal rather homogeneous powders after mechanical alloying and dense bulk samples after SPS. The microstructure observations show oxide particles and carbides on the grain boundaries and inside grains of the bcc matrix, which suggests elevated radiation damage resistance. The presence of nanoscale oxide particles (15–50 nm) in the matrix could significantly reduce the impact of aging embrittlement at high temperatures by affecting the chromium diffusion pathways in the ODS steel matrix. The addition of vanadium leads to an improvement of hardness to 4.83±0.43 GPa compared to 3.78±0.34 GPa for the sample without vanadium. Presented experimental results are promising in terms of research and development of FeCr and Al-based ODS materials tailored to operate under harsh conditions in generation IV fission reactors and fusion reactors. [Display omitted]
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2023.154700