Ionization energies, Coulomb explosion, fragmentation, geometric, and electronic structures of multicharged boron clusters B(n) (n=2-13)

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Akman, Nurten and Taş, Murat and Özdoğan, Cem and Boustani, İhsan (2011) Ionization energies, Coulomb explosion, fragmentation, geometric, and electronic structures of multicharged boron clusters B(n) (n=2-13). Physical Review B, 84 (7). ISSN 1098-0121

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Abstract

Based on the ab initio quantum chemical methods, we have determined fragmentation channels, ionization energies, and the Coulomb explosion of multicharged boron clusters B(n) (n = 2-13), where n is the cluster size. The electron-deficient boron clusters sustain more stability and hardly fragment when they are negatively charged. Stability of boron clusters decreases with increasing ionization. Only by the first ionization the odd-size clusters are more stable than the even-size clusters. Further ionizations cause the repulsive Coulomb force between the constituent atoms to get stronger, and lead first to metastable states, then to the Coulomb explosion of clusters. None of the cationic boron clusters studied remain stable after six times ionization. The critical charge for metastability is estimated as Q(m) <= n/2 for even-size clusters, and Q(m) <= 1/2 (n - 1) for odd-size clusters. In addition, the critical charge for the Coulomb explosion is found to be Q(c) = n/2 + 1 for even-size clusters, and Q(c) = 1/2(n + 1) for odd-size clusters. Relative stability of clusters with respect to their nearest neighbors is determined from the analysis of their second energy difference data. Several dissociation channels of B(n)(+) and B(13)(Q) isomers with the lowest fragmentation energies are presented. All of the vibrational frequencies are found positive indicating that no transition state is possible for the clusters studied. Reliability of our data is verified with a good agreement with experimental results.
Item Type: Article
Additional Information: Article Number: 075463
Subjects: Q Science > QC Physics
Divisions: Sabancı University Nanotechnology Research and Application Center
Faculty of Engineering and Natural Sciences
Depositing User: Murat Taş
Date Deposited: 26 Oct 2011 14:42
Last Modified: 30 Jul 2019 14:17
URI: https://research.sabanciuniv.edu/id/eprint/17301

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