Strain Release of Fused Pentagons in Fullerene Cages by Chemical Functionalization
- PMID: 30884036
- DOI: 10.1002/anie.201901678
Strain Release of Fused Pentagons in Fullerene Cages by Chemical Functionalization
Abstract
According to the isolated pentagon rule (IPR), for stable fullerenes, the 12 pentagons should be isolated from one another by hexagons, otherwise the fused pentagons will result in an increase in the local steric strain of the fullerene cage. However, the successful isolation of more than 100 endohedral and exohedral fullerenes containing fused pentagons over the past 20 years has shown that strain release of fused pentagons in fullerene cages is feasible. Herein, we present a general overview on fused-pentagon-containing (i.e. non-IPR) fullerenes through an exhaustive review of all the types of fused-pentagon-containing fullerenes reported to date. We clarify how the strain of fused pentagons can be released in different manners, and provide an in-depth understanding of the role of fused pentagons in the stability, electronic properties, and chemical reactivity of fullerene cages.
Keywords: endohedral fullerenes; exohedral fullerenes; fullerenes; fused pentagons; isolated pentagon rule.
© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.
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