利用第一原理法研究先进铀-硅化合物的力学性能

IF 1.6 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

The European Physical Journal B Pub Date : 2024-07-03 DOI:10.1140/epjb/s10051-024-00736-x

Hengfeng Gong, Daxi Guo, Jianhan Zhai, Jiwei Wang, Minzhou Chen, Lixiang Wu, Jiaxiang Xue, Yehong Liao

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引用次数: 0

摘要

由于具有高导热性和较高的裂变密度，目前最受欢迎的事故耐受燃料选择之一是铀硅燃料。遗憾的是，目前有关硅烷燃料的数据非常有限。本研究基于一些几何结构假设，利用密度泛函理论（DFT）对铀硅化合物的电子特性、弹性常数和硬度进行了系统预测。计算结果表明，U3Si2、β-U3Si 和 γ-U3Si 化合物具有金属脆性，这与之前的实验结果非常吻合。富含硅的 USi1.84 化合物呈现韧性。通过分析剪切各向异性因子，可以发现 U3Si2、β-U3Si 和富含硅的 USi1.84 具有各向异性的特征，而 γ-U3Si 则是各向同性的。此外，在 U3Si2、β-U3Si、γ-U3Si 和富含 Si 的 USi1.84 化合物中，γ-U3Si 最硬，而富含 Si 的 USi1.84 最软，那么根据 Voigt 硬度计算，U3Si2 比 β-U3Si 硬得多。我们的计算结果比实验数据高估了 U3Si2 的硬度值，这主要是因为模型可能是理想的，没有考虑缺陷和微观结构。这项工作的理论研究有望为先进燃料棒性能分析中的物理模型提供参数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

The mechanical properties of advanced U–Si compounds using first principles method

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The mechanical properties of advanced U–Si compounds using first principles method

Due to high thermal conductivity and higher fissile density, one of the most options being pursued for accident-tolerant fuels is U–Si fuels. Unfortunately, the data available for U–Si fuels are rather limited now. Based on a few assumptions regarding geometry structures, electronic properties, elastic constants and hardness are predicted systematically for U–Si compounds using density functional theory (DFT) in this work. The calculation results show that the U₃Si₂, β-U₃Si and γ-U₃Si compounds are metallic and brittle, which is in good agreement with the previous experimental results. The Si-rich USi_1.84 compound presents the ductile. By analyzing shear anisotropy factors, it is found that the U₃Si₂, β-U₃Si and Si-rich USi_1.84 have the anisotropic characteristics, while the γ-U₃Si is isotropic. Moreover, among the U₃Si₂, β-U₃Si, γ-U₃Si and Si-rich USi_1.84 compounds, the γ-U₃Si is hardest and Si-rich USi_1.84 is softest, then U₃Si₂ is much harder than that of β-U₃Si by the Voigt hardness calculations. The hardness value of U₃Si₂ is overestimated in our calculation than experimental data, mainly because the model may be ideal without considering defects and microstructure. The theoretical investigation of this work will be expected to provide parameters for the physical models in the advanced fuel rod performance analysis.