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非晶态合金计算机模拟的新方法:综述

New Approaches to the Computer Simulation of Amorphous Alloys: A Review.

作者信息

Valladares Ariel A, Díaz-Celaya Juan A, Galván-Colín Jonathan, Mejía-Mendoza Luis M, Reyes-Retana José A, Valladares Renela M, Valladares Alexander, Alvarez-Ramirez Fernando, Qu Dongdong, Shen Jun

机构信息

Instituto de Investigaciones en Materiales, Universidad Nacional Autónoma de México, Ciudad Universitaria, Apartado Postal 70-360, Mexico, D.F. 04510, Mexico.

Facultad de Ciencias, Universidad Nacional Autónoma de Mexico, Ciudad Universitaria, Apartado Postal 70-542, Mexico, D.F. 04510, Mexico.

出版信息

Materials (Basel). 2011 Apr 13;4(4):716-781. doi: 10.3390/ma4040716.

DOI:10.3390/ma4040716
PMID:28879948
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5448518/
Abstract

In this work we review our new methods to computer generate amorphous atomic topologies of several binary alloys: SiH, SiN, CN; binary systems based on group IV elements like SiC; the GeSe chalcogenide; aluminum-based systems: AlN and AlSi, and the CuZr amorphous alloy. We use an ab initio approach based on density functionals and computationally thermally-randomized periodically-continued cells with at least 108 atoms. The computational thermal process to generate the amorphous alloys is the undermelt-quench approach, or one of its variants, that consists in linearly heating the samples to just below their melting (or liquidus) temperatures, and then linearly cooling them afterwards. These processes are carried out from initial crystalline conditions using short and long time steps. We find that a step four-times the default time step is adequate for most of the simulations. Radial distribution functions (partial and total) are calculated and compared whenever possible with experimental results, and the agreement is very good. For some materials we report studies of the effect of the topological disorder on their electronic and vibrational densities of states and on their optical properties.

摘要

在这项工作中,我们回顾了用于计算机生成几种二元合金非晶原子拓扑结构的新方法:硅氢化物(SiH)、氮化硅(SiN)、碳氮化物(CN);基于IV族元素的二元体系,如碳化硅(SiC);锗硒硫族化合物(GeSe);铝基体系:氮化铝(AlN)和铝硅合金(AlSi),以及铜锆非晶合金。我们采用基于密度泛函的从头算方法,以及具有至少108个原子的计算热随机化周期性连续晶胞。生成非晶合金的计算热过程是欠熔淬火方法或其变体之一,该方法包括将样品线性加热至略低于其熔点(或液相线)温度,然后再线性冷却。这些过程从初始晶体条件开始,使用短时间步长和长时间步长进行。我们发现,对于大多数模拟而言,四倍于默认时间步长的步长就足够了。只要有可能,就计算径向分布函数(部分和总函数)并与实验结果进行比较,结果吻合得非常好。对于某些材料,我们报告了拓扑无序对其电子态密度、振动态密度以及光学性质影响的研究。

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