Unraveling the flexible aromaticity of CH: a 2D superatomic-molecule theory

Phenalenyl (C 13 H 9 ) is the smallest triangular unit of a graphene nanosheet, and has been experimentally verified to be stable in radical (C 13 H 9 &z.rad;), cationic (C 13 H 9 + ), and anionic (C 13 H 9 − ) states. All these three species feature high symmetry and stability as well as deloca...

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Published in:Physical chemistry chemical physics : PCCP 2023-03, Vol.25 (12), p.8439-8445
Main Authors: Li, Dan, Yan, Chen, Yuan, Qinqin, Shi, Lili, Cheng, Longjiu
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Summary:Phenalenyl (C 13 H 9 ) is the smallest triangular unit of a graphene nanosheet, and has been experimentally verified to be stable in radical (C 13 H 9 &z.rad;), cationic (C 13 H 9 + ), and anionic (C 13 H 9 − ) states. All these three species feature high symmetry and stability as well as delocalized π electrons, a visible sign of aromaticity, but their aromatic origin remains a challenge. This work reports new chemical insights into the π electrons of C 13 H 9 +/0/− and deciphers their aromaticity using a recently emerged two-dimensional (2D) superatomic-molecule theory. 12π-C 13 H 9 + , 13π-C 13 H 9 &z.rad;, and 14π-C 13 H 9 − are seen as triangular 2D superatomic molecules ◊ O 3 , ◊ O 3 − , and ◊ O 3 2− , respectively, where ◊ O denotes a 2D benzenoid superatom bearing 4 π electrons. Visualized superatomic Lewis structures show that each ◊ O can dynamically adjust its π electrons to satisfy the superatomic sextet rule of benzene via superatomic lone pairs and covalent bonds. C 13 H 9 +/0/− are representatives of adaptive aromaticity in the 2D superatomic-molecule system, exhibiting flexible π electronic structures to achieve shell-closure. Moreover, we specially adopt a progressive methodology to study the evolution of 2D periodic materials, by applying this theory to the similar family of C 6 H 3 N 7 , C 18 H 6 N 22 and graphitic carbon nitride (g-C 3 N 4 ) crystals, and meanwhile accounting for the special stability of g-C 3 N 4 . This work enriches 2D superatomic bonding chemistry and provides a useful strategy to design new 2D functional nanostructured materials. The π electrons of C 13 H 9 +/− are dynamically adjusted following the 2D superatomic-molecule theory to satisfy the superatomic sextet rule via superatomic bonds and lone pairs, resulting in flexible local aromaticity.
ISSN:1463-9076
1463-9084
DOI:10.1039/d3cp00125c