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纯态和单原子铜铟亚纳米团簇物理化学性质的计算洞察:一种密度泛函理论-遗传算法方法

Computational insights into the physico-chemical properties of pure and single-atom copper-indium sub-nanometre clusters: a DFT-genetic algorithm approach.

作者信息

Alotaibi Norah O, Abdulhussein Heider A, Alamri Shatha M, Hamza Noorhan Ali, Abo Nasria Abbas H

机构信息

Chemistry Department, Faculty of Science, King Abdulaziz University Jeddah 21589 Saudi Arabia.

Department of Chemistry, Faculty of Science, University of Kufa Najaf Iraq

出版信息

RSC Adv. 2025 Feb 20;15(8):5856-5875. doi: 10.1039/d4ra07404a. eCollection 2025 Feb 19.

DOI:10.1039/d4ra07404a
PMID:39980995
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11841672/
Abstract

Catalysis involving Cu-In nanoparticles represents an exciting area of technological advancement. However, our fundamental grasp of the mechanisms governing mixing within Cu-In clusters at the sub-nanometer scale and their gas-phase physicochemical properties remains inadequate. We have determined the global minima for gas-phase Cu-In clusters containing 3 to 10 atoms using the Mexican Enhanced Genetic Algorithm in conjunction with density functional theory. Simulations were also conducted for Cu and In atoms and their dimers at the same theoretical level. Comparative analyses were performed between mixed Cu-In systems and their pure counterparts, with pure Cu and In clusters being modeled up to 13 atoms. The findings indicate a 2D-3D transition for pure Cu clusters at 7 atoms, while for pure In clusters, this transition occurs at 5 atoms. For Cu-In nanoalloys, both cluster size and doping have been found to significantly and non-linearly impact cluster structures. Stability assessments, including binding energies, second differences in energy, and mixing energies, were used to evaluate the energetics, structures, and segregation tendencies of sub-nanometer Cu-In clusters. The most stable composition, as indicated by mixing energies, is achieved when the Cu to In ratio is equal or nearly equal. The HSE06 spin-projected band structure reveals that InCu displays magnetic properties akin to monometallic In. Conversely, the spin-projected band structure and partial density of states (PDOS) analysis for bimetallic CuIn show that the cluster is non-magnetic. Analysis of the topological parameters of Cu-Cu, In-In, and Cu-In bonds in bimetallic clusters, using the Quantum Theory of Atoms in Molecules (QTAIMs), indicates that these interactions are not purely closed-shell but involve significant covalent contributions.

摘要

涉及铜铟纳米颗粒的催化是一个令人兴奋的技术进步领域。然而,我们对亚纳米尺度下铜铟团簇内混合机制及其气相物理化学性质的基本理解仍然不足。我们使用墨西哥增强遗传算法结合密度泛函理论确定了含3至10个原子的气相铜铟团簇的全局最小值。还在相同理论水平上对铜原子、铟原子及其二聚体进行了模拟。对混合铜铟系统与其纯对应物进行了比较分析,对纯铜和铟团簇建模至13个原子。研究结果表明,纯铜团簇在7个原子时发生二维到三维的转变,而纯铟团簇在5个原子时发生这种转变。对于铜铟纳米合金,已发现团簇尺寸和掺杂都会对团簇结构产生显著的非线性影响。通过结合能、能量二阶差分和混合能等稳定性评估来评价亚纳米铜铟团簇的能量学、结构和偏析倾向。混合能表明,当铜与铟的比例相等或接近相等时,可实现最稳定的组成。HSE06自旋投影能带结构表明,铟铜表现出类似于单金属铟的磁性。相反,双金属铜铟的自旋投影能带结构和态密度(PDOS)分析表明该团簇是非磁性的。利用分子中原子的量子理论(QTAIMs)对双金属团簇中铜-铜、铟-铟和铜-铟键的拓扑参数进行分析,结果表明这些相互作用并非纯粹的闭壳层相互作用,而是涉及显著的共价贡献。

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