The thermal and elastic properties of U3Si5 and their variations induced by incorporated aluminum

•U3Si5 is determined to be a brittle and magnetic metal.•The elastic strength of U3Si5 is strongly anisotropic.•The brittleness of U3Si5 is due to a structural transition under tensile strains.•Aluminum incorporation enhances the toughness of U3Si5. Uranium silicide compounds have attracted intensiv...

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Published in:Journal of nuclear materials 2022-01, Vol.558, p.153331, Article 153331
Main Authors: Zha, Xian-Hu, Fu, Chen, Bai, Xiaojing, Lang, Jiajian, Luo, Jing-Ting, Zhang, Yaqing, Luo, Kan, Qin, Yanqing, Huang, Qing, Zhang, Rui-Qin, Li, Honglang, Tian, Yahui, Du, Shiyu
Format: Article
Language:English
Subjects:
Alternative fuels
Aluminum
Bonding strength
Elastic anisotropy
Elastic properties
First principles
Fuel technology
High temperature
Light water reactors
Mathematical analysis
Nuclear fuels
Shear modulus
Silicon
Tensile strain
Thermal conductivity
Transport theory
Uranium
Uranium silicide
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Summary:•U3Si5 is determined to be a brittle and magnetic metal.•The elastic strength of U3Si5 is strongly anisotropic.•The brittleness of U3Si5 is due to a structural transition under tensile strains.•Aluminum incorporation enhances the toughness of U3Si5. Uranium silicide compounds have attracted intensive attention as candidate alternative fuels in commercial light water reactors (LWRs). In this work, the electronic, thermal, mechanical and elastic properties of U3Si5 are comprehensively investigated based on first-principles density functional calculations and semi-classical Boltzmann transport theory. U3Si5 is determined to be a brittle and magnetic metal, and thermal conductivity is dominated by its electronic contribution at high temperature. The ratio between the bulk and shear moduli is 1.205. In addition, the elastic ideal strength is strongly anisotropic, with the minimum value only 6.831 GPa at a uniaxial tensile strain of 0.07. This low strength is mainly caused by an emerged structural transition forming silicon-silicon bonds to absorb strain energy. Moreover, the influences of aluminum incorporation on the structural and elastic properties, and thermal conductivities of U3Si5 are further studied. The aluminum atom prefers to replace the silicon atom at the vertex shared by the silicon triangles and pentagons. The incorporated atom impedes the structural transition, and enhances the toughness of U3Si5. The results from this work may provide useful clue for the improvement in the application of U3Si5. [Display omitted]
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2021.153331