Antiaromatic character of cycloheptatriene-bis-annelated indenofluorene framework mainly originated from heptafulvene segment

Yamamoto, Keitaro; Ie, Yutaka; Tohnai, Norimitsu; Kakiuchi, Fumitoshi; Aso, Yoshio

doi:10.1038/s41598-018-35839-w

Cited by 39 publications

(30 citation statements)

References 61 publications

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“…odd-membered polycycles (pentagons or heptagons), in the honeycomb lattice may have a considerable impact on the physicochemical properties of NGs, arising from local changes in strain and conjugation. [22][23][24][25] Under this scenario, atomically-precise bottom-up approaches have provided in the last decades an appealing playground for the design and investigation of NGs with perfectly defined structures and properties, 24,[26][27][28][29][30][31][32][33][34][35][36] in contrast to the well-known disadvantages such as non-regular edge structures or uncontrollable sizes presented by the top-down approach. 37 In this regard, on-surface chemical reactions have proven to be a versatile tool for the formation of stable molecular graphene structures that cannot be synthesized in solution.…”

Section: Introductionmentioning

confidence: 99%

On-Surface Synthesis of Non-Benzenoid Nanographenes by Oxidative Ring-Closure and Ring-Rearrangement Reactions

et al. 2020

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Nanographenes (NGs) have gained increasing attention due to their immense potential as tailor-made organic materials for nanoelectronics and spintronics. They exhibit a rich spectrum of physicochemical properties that can be tuned by controlling the size, the edge structure or by introducing structural defects in the honeycomb lattice. Here, we report the design and on-surface synthesis of NGs containing several odd-membered polycycles induced by a thermal procedure on Au(111). Our scanning tunneling microscopy, non-contact atomic force microscopy and scanning tunneling spectroscopy measurements, complemented by computational investigations, describe the formation of two non-benzenoid NGs (2A and 2B) containing four embedded azulene units in the polycyclic framework, via on-surface oxidative ring-closure reactions. Interestingly, we observe surface-catalyzed skeletal ring rearrangement reactions in the NGs, which lead to the formation of additional heptagonal rings as well as pentalene and as-indacene units in 2A and 2B, respectively. Both 2A and 2B on Au(111) exhibit narrow experimental frontier electronic gaps of 0.96 and 0.85 eV, respectively, and Fermi level pinning of their HOMO together with considerable electron transfer to the substrate. Ab initio calculations estimate moderate open-shell biradical characters for the NGs in gas phase.

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Section: Introductionmentioning

confidence: 99%

On-Surface Synthesis of Non-Benzenoid Nanographenes by Oxidative Ring-Closure and Ring-Rearrangement Reactions

et al. 2020

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“…In 2018, Aso and co‐workers reported the synthesis of 123 , a PAH consisting of benzo[1,2:4,5]di[7]annulene (BDA) and indenofluorene subunits (Scheme 31). [104] BDA is a 16π electron system, but possesses non‐aromatic character due to its twisted structure, [21] while indenofluorene possesses 20π electrons and exhibits antiaromatic and biradical character [105] . Tetra‐allylated compound 120 was prepared from the reaction of the corresponding diketone with allylmagnesium bromide.…”

Section: Metal‐promoted Reactionsmentioning

confidence: 99%

Construction of Heptagon‐Containing Molecular Nanocarbons

et al. 2021

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Molecular nanocarbons containing heptagonal rings have attracted increasing interest due to their dynamic behavior, electronic properties, aromaticity, and solid‐state packing. Heptagon incorporation can not only induce negative curvature within nanocarbon scaffolds, but also confer significantly altered properties through interaction with adjacent non‐hexagonal rings. Despite the disclosure of several beautiful examples in recent years, synthetic strategies toward heptagon‐embedded molecular nanocarbons remain relatively limited due to the intrinsic challenges of heptagon formation and incorporation into polyarene frameworks. In this Review, recent advances in solution‐mediated and surface‐assisted synthesis of heptagon‐containing molecular nanocarbons, as well as the intriguing properties of these frameworks, will be discussed.

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“…To date, various multi‐redox active C x H y molecules have been explored. These include, but are not limited to, nanographenes, [16–24] radicaloids (mostly based on diindenoarenes), [25–34] macrocycles, [35–39] fullerene fragments (including buckybowls), [40–45] nanographene‐buckybowl hybrids, [46] pentalene derivatives, [47] ethynylenes, [48] spiro‐compounds, [14] cumulenes, [49] other C x H y molecules with either the azulene, [50] barrelene, [51] fluoranthene, [52] fluorene, [53] diphenalene, [54] phenylene, [55] or Schwarzite framework, [56] and hydrofullerenes [57–61] . The redox properties of dissolved C x H y molecules are summarized in Table 1, where C x H y molecules that show at least six redox reactions (Scheme 1) are listed.…”

Section: Electrochemistry Of Cxhy Molecules As Solutesmentioning

confidence: 99%

“…The addition of functional groups to the periphery of C x H y molecules is a common solution to this limitation. Bulky substituents, such as tert ‐butyl groups and long alkyl chains, are often used to increase the solubility of C x H y molecules [21,47] . However, these substituents usually have larger molecular weights than non‐hydrocarbon‐based ones.…”

Section: Electrochemistry Of Cxhy Molecules As Solutesmentioning

confidence: 99%

Multi‐Redox Active Carbons and Hydrocarbons: Control of their Redox Properties and Potential Applications

Ueda

2021

The Chemical Record

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Precise control over redox properties is essential for high‐performance organic electronic devices such as organic batteries, electrochromic devices, and information storage devices. In this context, multi‐redox active carbons and hydrocarbons, represented as CxHy molecules (x≥1, y≥0), are highly sought after, because they can switch between multiple redox states. Herein, we outline the redox properties of CxHy molecules as solutes and adsorbed species. Furthermore, the limitations of evaluating their redox properties and the possible solutions are summarized. Additionally, the theoretical capacity (mAh/g) and gravimetric energy density (Wh/kg) of secondary batteries were estimated based on the redox properties of 185 CxHy molecules, which have primarily been reported in the last decade. Among them, seven CxHy molecules were found to have the potential to surpass the energy density of LiNi0.6Mn0.2Co0.2O2/graphite batteries. The use of CxHy molecules in multielectrochromic devices and multi‐bit memory is also explained. We believe that this review will encourage further utilization of CxHy molecules thereby promoting its applications in organic electronic devices.

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Antiaromatic character of cycloheptatriene-bis-annelated indenofluorene framework mainly originated from heptafulvene segment

Cited by 39 publications

References 61 publications

On-Surface Synthesis of Non-Benzenoid Nanographenes by Oxidative Ring-Closure and Ring-Rearrangement Reactions

On-Surface Synthesis of Non-Benzenoid Nanographenes by Oxidative Ring-Closure and Ring-Rearrangement Reactions

Construction of Heptagon‐Containing Molecular Nanocarbons

Multi‐Redox Active Carbons and Hydrocarbons: Control of their Redox Properties and Potential Applications

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