PGA: A new particle swarm optimization algorithm based on genetic operators for the global optimization of clusters

IF 3.4 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Journal of Computational Chemistry Pub Date : 2024-08-17 DOI:10.1002/jcc.27481

Kai Wang

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引用次数: 0

Abstract

We have developed a global optimization program named PGA based on particle swarm optimization algorithm coupled with genetic operators for the structures of atomic clusters. The effectiveness and efficiency of the PGA program can be demonstrated by efficiently obtaining the tetrahedral Au₂₀ and double-ring tubular B₂₀, and identifying the ground state ${ZrSi}_{17 - 20}^{-}$ clusters through the comparison between the simulated and the experimental photoelectron spectra (PESs). Then, the PGA was applied to search for the global minimum structures of ${Mg}_{n}^{-}$ (n = 3–30) clusters, new structures have been found for sizes n = 6, 7, 12, 14, and medium-sized 21–30 were first determined. The high consistency between the simulated spectra and the experimental ones once again demonstrates the efficiency of the PGA program. Based on the ground-state structures of these ${Mg}_{n}^{-}$ (n = 3–30) clusters, their structural evolution and electronic properties were subsequently explored. The performance on Au₂₀, B₂₀, ${ZrSi}_{17 - 20}^{-}$ , and ${Mg}_{n}^{-}$ (n = 3–30) clusters indicates the promising potential of the PGA program for exploring the global minima of other clusters. The code is available for free upon request.

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PGA：基于遗传算子的新粒子群优化算法，用于集群的全局优化

我们开发了一种名为 PGA 的全局优化程序，它基于粒子群优化算法和遗传算子，用于原子团簇结构的优化。通过模拟和实验光电子能谱（PES）的对比，我们有效地得到了四面体 Au20 和双环管状 B20，并识别了基态原子团簇，从而证明了 PGA 程序的有效性和高效性。然后，应用 PGA 寻找（n = 3-30）簇的全局最小结构，发现了 n = 6、7、12、14 和中等大小的 21-30 簇的新结构。模拟光谱与实验光谱的高度一致性再次证明了 PGA 程序的高效性。根据这些（n = 3-30）团簇的基态结构，随后对它们的结构演化和电子特性进行了探索。在 Au20、B20 和 (n = 3-30) 簇上的表现表明，PGA 程序在探索其他簇的全局最小值方面具有巨大潜力。该代码可应要求免费提供。

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来源期刊

Journal of Computational Chemistry 化学-化学综合

CiteScore

6.60

自引率

3.30%

发文量

247

审稿时长

1.7 months

期刊介绍： This distinguished journal publishes articles concerned with all aspects of computational chemistry: analytical, biological, inorganic, organic, physical, and materials. The Journal of Computational Chemistry presents original research, contemporary developments in theory and methodology, and state-of-the-art applications. Computational areas that are featured in the journal include ab initio and semiempirical quantum mechanics, density functional theory, molecular mechanics, molecular dynamics, statistical mechanics, cheminformatics, biomolecular structure prediction, molecular design, and bioinformatics.