Symmetry breaking during defect self-organization under irradiation

Yongfeng Zhang, Yipeng Gao, Cheng Sun, Daniel Schwen, Chao Jiang, Jian Gan
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引用次数: 7

Abstract

One of the most intriguing phenomena under radiation is the self-organization of defects, such as the void superlattices, which have been observed in a list of bcc and fcc metals and alloys when the irradiation conditions fall into certain windows defined by temperature and dose rate. A superlattice features a lattice parameter and a crystal structure. Previously, it has been shown that the superlattice parameter is given by the wavelength of vacancy concentration waves that develop when the uniform concentration field becomes unstable. This instability is driven thermodynamically by vacancy concentration supersaturation and affected by the irradiation condition. However, a theory that predicts the superlattice symmetry, i.e., the selection of superlattice structure, has remained missing decades after the first report of superlattices. By analyzing the nonlinear recombination between vacancies and self-interstitial-atoms (SIAs) in the discrete lattice space, this work establishes the physical connection between symmetry breaking and anisotropic SIA diffusion, allowing for predictions of void ordering during defect self-organization. The results suggest that while the instability is driven thermodynamically by vacancy supersaturation, the symmetry development is kinetically rather than thermodynamically driven. The significance of SIA diffusion anisotropy in affecting superlattice formation under irradiation is also indicated. Various superlattice structures can be predicted based on different SIA diffusion modes, and the predictions are in good agreement with atomistic simulations and previous experimental observations.

Abstract Image

辐照下缺陷自组织的对称性破缺
在辐射作用下,最有趣的现象之一是缺陷的自组织,如空洞超晶格,当辐射条件落入由温度和剂量率定义的特定窗口时,在一系列bcc和fcc金属和合金中观察到。超晶格具有晶格参数和晶体结构。先前已经证明,当均匀浓度场变得不稳定时产生的空位浓度波的波长给出了超晶格参数。这种不稳定性是由空位浓度过饱和和辐照条件驱动的。然而,预测超晶格对称性的理论,即超晶格结构的选择,在超晶格首次报道后的几十年里仍然缺失。通过分析离散晶格空间中空位和自间隙原子(SIAs)之间的非线性复合,本工作建立了对称破缺和各向异性SIA扩散之间的物理联系,从而可以预测缺陷自组织过程中的空隙有序。结果表明,虽然不稳定性是由空位过饱和引起的热力学驱动,但对称发展是由动力学而不是热力学驱动的。同时指出了辐照下SIA扩散各向异性对超晶格形成的影响。基于不同的SIA扩散模式可以预测不同的超晶格结构,并且预测结果与原子模拟和先前的实验观测结果很好地吻合。
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期刊介绍: Journal of Materials Science: Materials Theory publishes all areas of theoretical materials science and related computational methods. The scope covers mechanical, physical and chemical problems in metals and alloys, ceramics, polymers, functional and biological materials at all scales and addresses the structure, synthesis and properties of materials. Proposing novel theoretical concepts, models, and/or mathematical and computational formalisms to advance state-of-the-art technology is critical for submission to the Journal of Materials Science: Materials Theory. The journal highly encourages contributions focusing on data-driven research, materials informatics, and the integration of theory and data analysis as new ways to predict, design, and conceptualize materials behavior.
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