Abstract
The local structures of U-Co melts have been studied by first-principle calculations. Two sub-peaks are observed in the first peaks of U-U pair distribution functions. The Voronoi polyhedral analyses also show two separate core-shell U-U distances. Therefore, the calculated results propose that U atoms will play dual roles, “chemical” and “topological”, in the local structures of U-Co melts. In addition, the chemical effect of U atoms will be strengthened when containing more U atoms. The interaction of Co and U atoms is slightly affected by the compositions. The Co-centered clusters are mostly prism-like or antiprism-like polyhedral, which can be predicted by the solute-solvent model. The distribution of the coordinated numbers of Co atoms is much narrower than that of U atoms, showing relatively stable Co-centered clusters. The chemical and topological roles of U atoms are intuitively observed in the electron density of U-Co melts, which presents both metallic and covalent bonding characteristics for U-U bonds. In the end, we conclude that the partial localization of U 5f-electron is responsible for the dual roles of U atoms. The present results provide a theoretical understanding of the origin of the local structures of U-Co melts.
Highlights
Uranium-based materials have been used in energy power, aerospace, biomedical instrument, and military weapons due to their high hardness and radioactivity
The present work will provide a theoretical view to understand the local structures of U-Co melts
Cubic supercells containing 200 atoms with periodic boundary conditions were constructed by a random distribution of U and Co atoms, which were used to act as the original structures for the subsequent dynamic process
Summary
Uranium-based materials have been used in energy power, aerospace, biomedical instrument, and military weapons due to their high hardness and radioactivity. Huang et al exploited U-Co-Al and U-Co-B metallic glasses (MGs) by melt-spin quenching method, in which the corrosion resistance is better than that in crystal alloys (Huang et al, 2016; Xu et al, 2018). The local structures of U-Co melts (U50Co50, U67Co33, and U86Co14) are studied by first-principle dynamics calculations. Several structural indicators, such as pair distribution function, Voronoi polyhedra, and coordination number, are used to correlate the structural characteristics with melt compositions. The present work will provide a theoretical view to understand the local structures of U-Co melts
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