Energy and structure of copper clusters (n=70-150) studied by the Monte Carlo computer simulation 被引量：2

Energy and structure of copper clusters (n=70-150) studied by the Monte Carlo computer simulation

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摘要 The structure and binding energy of copper clusters of the size range 70 to 150 were studied by using the embeddedatom method. The stability of the structure of the clusters was studied by calculating the average binding energy per atom, first difference energy and second difference energy of copper cluster. Most of the copper clusters of the size n=70-150 adopt an icosahedral structure. The results show that the trends are in agreement with theoretic prediction for copper clusters. The most stable structures for copper clusters are found at n=77, 90, 95, 131, 139. The structure and binding energy of copper clusters of the size range 70 to 150 were studied by using the embeddedatom method. The stability of the structure of the clusters was studied by calculating the average binding energy per atom, first difference energy and second difference energy of copper cluster. Most of the copper clusters of the size n=70-150 adopt an icosahedral structure. The results show that the trends are in agreement with theoretic prediction for copper clusters. The most stable structures for copper clusters are found at n=77, 90, 95, 131, 139.

作者潘小东盖志刚李公平

机构地区 School of Nuclear Science and Technology

出处《Chinese Physics B》 SCIE EI CAS CSCD 2008年第9期3329-3335,共7页 中国物理B（英文版）

基金 supported by the National Natural Science Foundation of China (Grant No 10375028)

关键词 copper cluster STRUCTURE ENERGY copper cluster, structure, energy

分类号 O561 [理学—原子与分子物理] TP391.9 [自动化与计算机技术—计算机应用技术]

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1Hansen P L, Wagner J B, Helveg S, Rostrup-Nielsen J R, Clausen B S and Topsφe H 2002 Science 295 2053
2Valden M, Lai X and Goodman D W 1998 Science 281 1647
3Park S J, Taton T A and Mirkin C A 2002 Science 295 1503
4Kabir M, Mookerjee A and Bhattacharya A K 2004 Phys. Rev. A 69 043203
5Erkoc S and Shaltaf R 2004 Phys. Rev. A 60 3053
6Christensen O B, Jacobsen K W, Ncrskov J K and Manninen M 1991 Phys. Rev. Left. 66 2219
7Delley B, Ellis D E, Freeman A J, Baerends E J and Post D 1983 Phys. Rev. B 27 2132
8Jug K, Zimmermann B, Calaminici P and Koster A M 2002 J. Chem. Phys. 116 4497
9Jaque P and Toro-Labbe A 2002 J. Chem. Phys. 117 3208
10Darby S, Mortimer-Jones T V, Johnston R L and Roberts C 2002 J. Chem. Phys. 116 1536

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1李公平,何山虎,丁宝卫,张小东,丁印锋,包良满,刘正民,朱德彰.铜团簇束在硅上碰撞沉积的薄膜形貌和方块电阻[J].兰州大学学报（自然科学版）,2004,40(5):31-33. 被引量：3
2王广厚.团簇物理的新进展（Ⅰ）[J].物理学进展,1994,14(2):121-172. 被引量：101
3张梅玲,李公平,郭向云.铜团簇Cu_n(n=2-60)的基态能量与几何结构的Monte Carlo模拟[J].原子与分子物理学报,2005,22(3):515-519. 被引量：24
4齐卫宏,汪明朴,李周,谢丹.分子动力学模拟铜纳米团簇的结构稳定性[J].中国有色金属学报,2005,15(11):1854-1858. 被引量：5
5盖志刚,李公平.铜团簇嵌入原子势模型的参数修正及应用[J].原子核物理评论,2007,24(1):76-79. 被引量：3
6Sarah Darby, Thomas V, Mortimer-Jones, et al. Theoretical Study of Cu-Au Nanoalloy Clusters Using a Genetic Algorithm[J]. J. Chem. Phys,2002,116(4) : 1 536-1 550.
7Mukul Kabir, Abhijit Mookerjee, Bhattacharya A K. Structure and Stability of Copper Clusters:A Tight-binding Molecular Dynamics Study[J]. Phys. Rev, 2004, A69 : 043203.
8Spasov V A,Lee T H,Ervin K. Threshold Collision-induced Dissociation of Anionic Copper Clusters and Copper Cluster Monocarbonyls[J]. J. Chem. Phyg ,2000,112(4):1 713-1 720.
9Yang Mingli , Koblar A Jackson, Christof Koehler, et al. Structure and Shape Variations in Intermediate-size Copper Clusters[J]. J. Chem. Phys. ,2006,124(2) ,4 308-4 314.
10Nicholas T Wilson, Roy L Johnston. A theoretical Study of Atom Ordering in Copper-gold Nanoalloy Clusters [J]. J. Mater. Chem,2002,12:2 913-2 922.

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3鞠思婷.玻璃态无序体系[J].国外科技新书评介,2013(11):14-14.
4光学相关论题自适应光学[J].中国光学,2005(4):105-105.
5王青军.让实验数据更真实——“水在0℃时开始结冰”实验教学探究[J].湖北教育（科学课）,2017,0(1):112-113.
6WANG Shuozhong,Theodore G. Birdsall(Shanghai University Shanghai 200072) (University of Michigan, U. S. A.).Computer simulation of tidal signal prediction in long range ocean acoustic travel-time measurements[J].Chinese Journal of Acoustics,1996,15(1):39-51.
7戴光泽,夏燕,荒木荣敏.粘弹性体的耗散效应与发展方程的系数矩阵[J].西南交通大学学报,2001,36(6):604-608. 被引量：3
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9孙祉伟,陈致英.Computer Simulation of Influence of Sedimentation on Rapid Coagulation[J].Chinese Physics Letters,2003,20(9):1634-1636.
10GUO Wei-Ming~1 LI Biao~(1,3)and CHEN Yong~(1,2,3)~1 Nonlinear Science Center and Department of Mathematics,Ningbo University,Ningbo 315211,China~2 Institute of Theoretical Computing,East China Normal University,Shanghai 200062,China~3 Key Laboratory of Mathematics Mechanization,the Chinese Academy of Sciences,Beijing 100080,China.An Extended Subequation Rational Expansion Method and Solutions of (2+1)-Dimensional Cubic Nonlinear Schr(?)dinger Equation[J].Communications in Theoretical Physics,2007(12):987-992.

Chinese Physics B

2008年第9期

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Energy and structure of copper clusters (n=70-150) studied by the Monte Carlo computer simulation 被引量：2

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