Antiaromatic Covalent Organic Frameworks Based on Dibenzopentalenes

Sprachmann, Josefine; Wachsmuth, Tommy; Bhosale, Manik; Burmeister, David; Smales, Glen J.; Kochovski, Zdravko; Grabicki, Niklas; Esser, Birgit; Dumele, Oliver

doi:10.26434/chemrxiv-2022-p0pjr

Cited by 3 publications

(4 citation statements)

References 83 publications

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“…The capacity retention was still 76.4 % after more than 500 cycles at 2 C when the material was compounded with CNTs for LIBs, and the capacity retention after 1000 cycles reaches an excellent 84 % at 5 C for MIBs. [108] Lu et al combined various modification methods such as high active sites, carbon material composite, and introduction of heteroatoms to designed a COFs cathode material S@TAPT-COFs@rGO with excellent comprehensive performance. [99] By replacing TAPA with TAPT containing triazine ring, more active sites C=N were introduced into the structure (Figure 10d).…”

Section: Design Of Highly Conductive Cofs Cathodementioning

confidence: 99%

Covalent Organic Frameworks as Electrode Materials for Alkali Metal‐ion Batteries

Cui,

Miao,

Peng

et al. 2024

Chemistry A European J

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Covalent organic frameworks (COFs) are a class of porous crystalline polymeric materials constructed by linking organic small molecules through covalent bonds. COFs have the advantages of strong covalent bond network, adjustable pore structure, large specific surface area and excellent thermal stability, and have broad application prospects in various fields. Based on these advantages, rational COFs design strategies such as the introduction of active sites, construction of conjugated structures, and carbon material composite, etc. can effectively improve the conductivity and stability of the electrode materials in the field of batteries. This paper introduces the latest research results of high‐performance COFs electrode materials in alkali metal‐ion batteries (LIBs, SIBs, PIBs and LSBs) and other advanced batteries. The current challenges and future design directions of COFs‐based electrode are discussed. It provides useful insights for the design of novel COFs structures and the development of high‐performance alkali metal‐ion batteries.

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Section: Design Of Highly Conductive Cofs Cathodementioning

confidence: 99%

Covalent Organic Frameworks as Electrode Materials for Alkali Metal‐ion Batteries

Cui,

Miao,

Peng

et al. 2024

Chemistry A European J

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“…98 Herein, by virtue of donor-acceptor combination, the migration of photogenerated electrons from the donor to the acceptor ligand is favored by a push-pull effect. 60…”

Section: Role Of Organic Moieties As Building Unitsmentioning

confidence: 99%

“…[57][58][59] Additionally, COFs can be structurally predesigned and functionalized by varying their organic synthons as per requirements. 60 The chemical and thermal stability of COFs is an added advantage in inhibiting photocorrosion during photocatalysis. Thus, COFs are applied for many photocatalytic transformations, including water splitting to hydrogen and oxygen evolution, CO 2 reduction, and organic transformations.…”

Section: Introductionmentioning

confidence: 99%

Strategic design of covalent organic frameworks (COFs) for photocatalytic hydrogen generation

et al. 2023

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“…9 Besides antiaromatic molecules with two degenerate SOMOs and a diradical character y0 of 1 (referred to as truly antiaromatic molecules in this article), there are molecules with a formal 4n πelectron system but reduced diradical character (between 0 and 1). 10 These molecules -including pentalene, dibenzopentalene, s-indacene, and biphenylene (Figure 1c) and their derivatives as well as different cyclooctatetraene derivatives -are often also referred to as antiaromatic, [11][12][13][14][15][16][17][18] even when the diradical character is low. However, the classification of such molecules as antiaromatic has been criticized, particularly for polycyclic molecules that feature both formal 4n and 4n+2 πelectron systems (such as dibenzopentalene and biphenylene, Figure 1c right).…”

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confidence: 99%

Concealed antiaromaticity

Glöcklhofer

2023

Preprint

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Numerous articles in the recent literature report molecules that are claimed to be antiaromatic, as they feature a formal 4n π-electron system. The purported antiaromaticity often serves well as an explanation for some of the observed properties, but it neglects the actual local aromaticity of the molecules, which often feature multiple subunits with 4n+2 π-electrons besides the formal 4n π-electron system. This has led to considerable criticism from those who believe that the term antiaromatic should not be used for any molecule with a formal 4n π-electron system but should be reserved for truly antiaromatic molecules. To reconcile the different viewpoints, the term and concept of concealed antiaromaticity is introduced here. The concept accepts that many of the molecules claimed to be antiaromatic are not truly antiaromatic. However, it acknowledges that this does not prevent those molecules from exhibiting behaviour under certain conditions that would normally be expected for antiaromatic molecules, due to the formal, concealed 4n π-electron system that characterizes these molecules. Based on the conditions under which the molecules can behave like antiaromatic molecules, three types of concealed antiaromaticity are distinguished here: concealed antiaromaticity revealable in redox reactions (Type I-CA), upon excitation (Type II-CA), and in intermolecular interactions (Type III-CA). The concept of concealed antiaromaticity will enable the conscious, rational design of molecules that show the desirable properties of antiaromatic molecules while avoiding or diminishing the undesirable properties, namely the low stability of truly antiaromatic molecules. This will yield molecules and materials with highly interesting properties for a broad range of applications, from organic electronics to supramolecular chemistry.

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Antiaromatic Covalent Organic Frameworks Based on Dibenzopentalenes

Cited by 3 publications

References 83 publications

Covalent Organic Frameworks as Electrode Materials for Alkali Metal‐ion Batteries

Covalent Organic Frameworks as Electrode Materials for Alkali Metal‐ion Batteries

Strategic design of covalent organic frameworks (COFs) for photocatalytic hydrogen generation

Concealed antiaromaticity

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