期刊
PHYSICAL CHEMISTRY CHEMICAL PHYSICS
卷 24, 期 6, 页码 4022-4041出版社
ROYAL SOC CHEMISTRY
DOI: 10.1039/d1cp05770g
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资金
- University Grant Commission (UGC)
- Indian Association for the Cultivation of Science (IACS)
Mechanistic investigations using Density Functional Theory have revealed the detailed mechanism of the functionalization of three fullerene cages, including different ring fusions and the effect of Li+ encapsulation. The results provide guidance for further research in fullerene chemistry.
Mechanistic investigations into the functionalization of three fullerene cages, viz. C-60, C-70, and C-36 through dehydrogenation of ammonia-borane (AB) have been conducted using Density Functional Theory (DFT). In this process of functionalization, different ring fusions, namely (6-6), (6-5) positions for C-60 and C-70, and an additional (5-5) for C-36 fullerene have been investigated. The optimized geometries of all the complexes and transition states have been characterized using the M06-2X functional in conjunction with the 6-31G(d) basis set. The effect of Li+-encapsulation on the energetics and activation barriers of H-2 attachment has also been examined. Although the process of functionalization of neutral fullerenes proceeds extensively through concerted pathways, a step-wise route has been observed for the encapsulated systems. NPA charge analysis and Wiberg bond index (WBI) have been used in order to detect the change in the nature of participating hydrogen atoms and validate the variation in the bond order of the C-C connectivity respectively upon hydrogenation. GCRD parameters have also been calculated to explicate the electronic properties of the hydrogenated products. The (6-6) hydrogenation is observed to be favoured thermodynamically and kinetically for both neutral and Li+-encapsulated C-60 and C-70, while (5-5) is found to be the most preferred site for C-36 systems. Our theoretical exploration suggests that the covalent functionalization of the fullerene cages can be done successfully via AB resulting in the stabilization of these systems. In short, the present work will provide a general idea about the detailed mechanism related to the functionalization of fullerene cages, which will further motivate researchers in fullerene chemistry.
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