Ultrastable actinide endohedral borospherenes

Since the discovery of the first all-boron fullerenes B , metal-doped borospherenes have received extensive attention. So far, in spite of theoretical efforts on metalloborospherenes, the feasibility of actinide analogues remains minimally explored. Here we report a series of actinide borospherenes...

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Bibliographic Details
Published in:Chemical communications (Cambridge, England) England), 2018-03, Vol.54 (18), p.2248-2251
Main Authors: Wang, Cong-Zhi, Bo, Tao, Lan, Jian-Hui, Wu, Qun-Yan, Chai, Zhi-Fang, Gibson, John K, Shi, Wei-Qun
Format: Article
Language:English
Subjects:
actinides
Aromaticity
Bonding
Boron
borospherenes
Cages
Chemical bonds
Density functional calculations
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
metalloborospherenes
Thorium
Uranium
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Summary:Since the discovery of the first all-boron fullerenes B , metal-doped borospherenes have received extensive attention. So far, in spite of theoretical efforts on metalloborospherenes, the feasibility of actinide analogues remains minimally explored. Here we report a series of actinide borospherenes AnB (An = U, Th; n = 36, 38, and 40) using DFT-PBE0 calculations. All the AnB complexes are found to possess endohedral structures (An@B ) as the global minima. In particular, U@B (C , A ) and Th@B (D , A ) exhibit nearly ideal endohedral borospherene structures. The C U@B and D Th@B complexes are predicted to be highly robust both thermodynamically and dynamically. In addition to the actinide size match to the cage, the covalent character of the metal-cage bonding in U@B and Th@B affords further stabilization. Bonding analysis indicates that U@B and Th@B can be qualified as 32-electron systems, and Th@B exhibits 3D aromaticity with σ plus π double delocalization bonding. The results demonstrate that doping with appropriate actinide atoms is promising to stabilize diverse borospherenes, and may provide routes for borospherene modification and functionalization.
ISSN:1359-7345
1364-548X
DOI:10.1039/c7cc09837e