Experimental consideration of covalent‐bonding interactions in stacks of singlet biradicals having Kekulé structures

Shimizu, Akihiro; Nakano, Masayoshi; Hirao, Yasukazu; Kubo, Takashi

doi:10.1002/poc.1873

Cited by 25 publications

(20 citation statements)

References 67 publications

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“…couplings are comparable in magnitude as wast he case for Kubo's chain. [87,108,109] The situation in Haddon's SBPLYm etallic conductors (Figure 15 c) is different because the number of electrons available for pancakeb ondingi sh alf (1/4 band filling) of that of Kubo's chain corresponding to PBO = 1/2; [16d, 110] still the couplings within and between the radicals upplying units are similari nm agnitude and produce wide conductions bands. [111] Opportunities for Pancake Bonding in Graphene Nanoflakes Figure 16 illustrates the relationship between ag raphene sheet and various triangular multiradicals, such as PLY( 1), and two other triangulene shaped graphene flakes.I th as been well established [112][113][114][115] that as the size of hydrogen terminated highly conjugated nanoflakes increases, their edge atoms develop significant p-type polyradical character depending on the size, the shape and topology of the flakes.W hile PLY [37] and trioxotriangulene ( Figure 1c)a nd its derivatives [99] are radicals and form single pancake bonds,d iradicals and multiradicals can form multiple pancake bonds or multiple single pancake bonds as discussed in this review.T he XRD of the trioxotriangulene molecules demonstrated pancake bondinga lso confirmed by DFT analysis.…”

Section: One-dimensional Pancake-bonded Assembliesmentioning

confidence: 99%

“…The larger blue ellipses in Scheme point to antiferromagnetic coupling within the molecular unit, while the smaller red ellipses indicate antiferromagnetic coupling between the molecules via pancake bonding . A reasonable hypothesis consistent with the experiments is that these two couplings are comparable in magnitude as was the case for Kubo's chain . The situation in Haddon's SBPLY metallic conductors (Figure c) is different because the number of electrons available for pancake bonding is half (1/4 band filling) of that of Kubo's chain corresponding to PBO=1/2; still the couplings within and between the radical supplying units are similar in magnitude and produce wide conductions bands …”

Section: One‐dimensional Pancake‐bonded Assembliesmentioning

confidence: 99%

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Pancake Bonding: An Unusual Pi‐Stacking Interaction

Kertész

2018

Chemistry A European J

193

227

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A category of parallel π-stacking interaction, termed pancake bonding, is surveyed. The main characteristics are: the interaction occurs among radicals with highly delocalized π-electrons in their singly occupied molecular orbitals (SOMOs), the contact distances in the π-stacking direction are shorter than the typical van der Waals distances, and the stabilization obtained by the bonding combination of the SOMO orbitals leads to direct atom-to-atom overlap with strong orientational preferences. These atypical intermolecular interactions contain a component of electron sharing between the radicals that can be viewed as covalent-like. Pancake bonded dimers characteristically have low-lying singlet and triplet states and show characteristic interlayer vibrational modes. Pancake bonded aggregates serve as molecular components in many conducting and other functional organic materials. The role of van der Waals (vdW) interactions in pancake bonded dimers, chains, and other aggregates is different from closed shell vdW aggregates: here the Pauli repulsions reduce the attractive dispersion interaction significantly. Fluxionality between π- and σ-bonded aggregates often occur in the context of pancake bonding. Both experimental and computational aspects are reviewed.

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Section: One-dimensional Pancake-bonded Assembliesmentioning

confidence: 99%

Section: One‐dimensional Pancake‐bonded Assembliesmentioning

confidence: 99%

Pancake Bonding: An Unusual Pi‐Stacking Interaction

Kertész

2018

Chemistry A European J

193

227

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“…Conjugated biradical systems can be broadly divided into two types, namely Kekule and non-Kekule systems. [19,21] Both these categories can be drawn as having resonance between the valence bond structures with some of the structures having a closed-shell form. Kekule-type biradicals are characterized by having all the atoms' valencies satisfied.…”

Section: Introductionmentioning

confidence: 99%

Substituents Destabilize the Molecule by Increasing Biradicaloid Character and Stabilize by Intramolecular Charge Transfer in the Derivatives of Benzobis(thiadiazole) and Thiadiazolothienopyrazine: A Computational Study

et al. 2011

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Keeping in view the possible applications of singlet open-shell molecules as semiconductors, non-classical derivatives of the heterocyclic rings benzobis(thiadiazole) (BBT) and its positional isomer thiadiazolothienopyrazine (TTP) are characterized using DFT methodologies. M06-2X, B3LYP and BHandHLYP functionals were used to optimize the geometries and estimate the vertical transition energies. It is observed that unlike the BHandHLYP functional (50% exchange), which gives rise to spin-contaminated solutions for all molecules in the series, M06-2X (54% exchange) affords a wavefunction either with no instability or negligible instability for most of the molecules. The results are compared with the earlier reported experimental data and those obtained herein using the spin-flip (SF)-5050 method. It is found that B3LYP does not fare well while on the other hand the M06-2X and SF-50-50 are in good agreement with the experimental results. It is seen that M06-2X TD-DFT for the molecules can be carried out without major spin contamination and also that the more time-consuming CI can be avoided for the calculation of transition energies. The biradical nature of the molecules is estimated by the singlet-triplet gap. Intramolecular charge transfer is calculated. It is found that the ring substituents donate charge in the ground state, creating a zwitterionic structure. Thus the substituents play an interesting dual role, decreasing the stability of the molecule by increasing the biradical character (small HOMO-LUMO gap), and stabilization of this ground state by intramolecular charge transfer.

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“…[4] The observedi ntrastack contacts cannot be described by classical van der Waals p-stacking, but rather by the p-stacking aggregates drivenb yt he formation of ab ond (called pancake bonding) resultingf rom the presence of singlyo ccupied molecular orbitals (SOMOs) in the constituting monomers. [6] This strong p-electron coupling provides ap lausible path for electron or hole transport in materials exhibiting unusuale lectrical conductivity, [1,7] and varied magnetic [8] or optical propertiesd ue to their low lying triplet states. [6] This strong p-electron coupling provides ap lausible path for electron or hole transport in materials exhibiting unusuale lectrical conductivity, [1,7] and varied magnetic [8] or optical propertiesd ue to their low lying triplet states.…”

mentioning

confidence: 99%

“…[5] Ac ovalent-like through-space p-stacking multi-electron/multicentre interaction termed as pancake bonding is observed in various radical dimers. [6] This strong p-electron coupling provides ap lausible path for electron or hole transport in materials exhibiting unusuale lectrical conductivity, [1,7] and varied magnetic [8] or optical propertiesd ue to their low lying triplet states. [9] In this paper, we describe the first instanceo fp ancake bonding extending beyond as ingle pair (dimers) of semiquinone radicals.…”

mentioning

confidence: 99%

Pancake Bonding in π‐Stacked Trimers in a Salt of Tetrachloroquinone Anion

Molčanov

Mou

Kertész

et al. 2018

Chemistry A European J

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The crystal structure of [4-damp]) [Cl Q] (4-damp=4-dimethylamino-N-methylpyridinium, Cl Q=tetrachloroquinone) salt is built up from slipped columnar stacks of quinoid rings composed of closely bound trimers with the intra-trimer separation distance of 2.84 Å and total charge of -2 whereas the inter-trimer distance is 3.59 Å. The individual rings exhibit partial negative charges that are distributed unevenly among the three Cl Qs in the trimer. The strong interactions within a trimer (Cl Q) have a partially covalent character with two-electron/multicentered bonding, that is extended over three rings, plausibly termed as "pancake bonding". The electron pairing within this multicentre bond leads to the fact that the crystals are diamagnetic and act as insulators. The studies of the structure and nature of bonding are based on X-ray charge density analysis and density functional theory.

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Experimental consideration of covalent‐bonding interactions in stacks of singlet biradicals having Kekulé structures

Cited by 25 publications

References 67 publications

Pancake Bonding: An Unusual Pi‐Stacking Interaction

Pancake Bonding: An Unusual Pi‐Stacking Interaction

Substituents Destabilize the Molecule by Increasing Biradicaloid Character and Stabilize by Intramolecular Charge Transfer in the Derivatives of Benzobis(thiadiazole) and Thiadiazolothienopyrazine: A Computational Study

Pancake Bonding in π‐Stacked Trimers in a Salt of Tetrachloroquinone Anion

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