A DFT + U Study on the Stability of Small CuN Clusters (N = 3–6 Atoms): Calculation of Phonon Frequencies

IF 1.9 Q3 PHYSICS, CONDENSED MATTER

Condensed Matter Pub Date : 2023-09-11 DOI:10.3390/condmat8030081

Luis A. Alcalá-Varilla, Rafael E. Ponnefz-Durango, Nicola Seriani, Eduard Araujo-Lopez, Javier A. Montoya

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Abstract

Despite the interest in copper clusters, a consensus on their atomic structure is still lacking. The experimental observation of isolated clusters is difficult, and theoretical predictions vary widely. The latter is because one must adequately describe the closed shell of d electrons both in its short- and long-range effects. Herein, we investigate the stability of small copper clusters (CuN, N = 3–6 atoms) using spin-polarized DFT calculations under the GGA approximation, the Hubbard U correction, and the van der Waals forces. We found that the spin-polarized and vdW contributions have little effect on the binding energies of the isomers. The inclusion of U represents the most relevant contribution to the ordering of the CuN isomers, and our calculated binding energies for the clusters agreed with the experimental values. We also found that atomic relaxations alone are not enough to determine the stability of small copper clusters. It is also necessary to build the energy landscape or calculate the vibrational frequencies of the isomers. We found that the vibrational frequencies of the isomers were in the THz range and the normal modes of vibration were discrete. This approach is relevant to future studies involving isolated or supported copper clusters.

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N = 3-6个原子的CuN簇稳定性的DFT + U研究:声子频率的计算

尽管对铜簇很感兴趣，但对其原子结构仍缺乏共识。对孤立星团的实验观察是困难的，理论预测差异很大。后者是因为必须充分描述d电子的闭合壳层的短期和长期效应。本文利用GGA近似、Hubbard U校正和范德华力下的自旋极化DFT计算，研究了小铜团簇(N = 3-6个原子)的稳定性。我们发现自旋极化和vdW的贡献对同分异构体的结合能影响很小。U的加入对CuN同分异构体的排序起着最重要的作用，我们计算的簇的结合能与实验值一致。我们还发现，单靠原子弛豫不足以确定小铜团簇的稳定性。建立能量分布图或计算同分异构体的振动频率也是必要的。我们发现异构体的振动频率在太赫兹范围内，振型是离散的。这种方法与未来涉及分离或支持铜簇的研究有关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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