从炼金术机器学习看高熵合金的表面偏析

Arslan Mazitov, Maximilian A Springer, Nataliya Lopanitsyna, Guillaume Fraux, Sandip De, Michele Ceriotti
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引用次数: 0

摘要

高熵合金(HEAs)含有几种接近等摩尔比例的金属元素,因其独特的机械性能长期以来一直备受关注。最近,高熵合金因其巨大的设计空间和各组分之间的协同效应,已成为开发新型异相催化剂的一个前景广阔的平台。在这项工作中,我们使用了一种机器学习势能,它可以同时模拟多达 25 种过渡金属,以研究不同元素在 HEA 表面的分离趋势。我们以之前开发的完全用于晶体体相的势能为起点,并证明由于该模型的物理启发函数形式,只需添加更少数量的缺陷构型就能描述表面现象。随后,我们介绍了几项关于表面偏析的计算研究,其中包括对 25 种元素合金的模拟,该模拟提供了对各种元素相对表面倾向的粗略估计,以及对 CoCrFeMnNi 和 IrFeCoNiCu 的针对性研究,这些研究进一步验证了该模型,并为异相催化合金的建模和设计提供了指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Surface segregation in high-entropy alloys from alchemical machine learning
High-entropy alloys (HEAs), containing several metallic elements in near-equimolar proportions, have long been of interest for their unique mechanical properties. More recently, they have emerged as a promising platform for the development of novel heterogeneous catalysts, because of the large design space, and the synergistic effects between their components. In this work we use a machine-learning potential that can model simultaneously up to 25 transition metals to study the tendency of different elements to segregate at the surface of a HEA. We use as a starting point a potential that was previously developed using exclusively crystalline bulk phases, and show that, thanks to the physically-inspired functional form of the model, adding a much smaller number of defective configurations makes it capable of describing surface phenomena. We then present several computational studies of surface segregation, including both a simulation of a 25-element alloy, that provides a rough estimate of the relative surface propensity of the various elements, and targeted studies of CoCrFeMnNi and IrFeCoNiCu, which provide further validation of the model, and insights to guide the modeling and design of alloys for heterogeneous catalysis.
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