Substitution‐Pattern‐ and Counteranion‐Depending Ion‐Pairing Assemblies Based on Electron‐Deficient Porphyrin–Au<sup>III</sup> Complexes

Tanaka, Hiroki; Haketa, Yohei; Yasuda, Nobuhiro; Maeda, Hiromitsu

doi:10.1002/asia.201900422

Cited by 16 publications

(10 citation statements)

References 26 publications

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“…19a), in order to control the electronic states and resulting ion-pairing assemblies. 54 The electron-deficient character of C 6 F 5 -substituted porphyrin-Au III complexes was confirmed by electrostatic potential (ESP) diagrams, suggesting that the electron deficiency of the porphyrin core increases with the introduction of C 6 F 5 units (Fig. 19b).…”

Section: -3 Metal Complexes Of π-Electronic Ligands For π-Electronimentioning

confidence: 90%

“…This type of electron-withdrawing character of peripheral substituents is crucial for tuning interionic interactions. 54 3-6. Aliphatic porphyrin-Au III complexes for dimensioncontrolled assemblies Introduction of aliphatic long alkyl chains into an appropriate π-electronic unit affords soft materials comprising the stacking core π-units supported by van der Waals interactions of alkyl chains.…”

Section: -3 Metal Complexes Of π-Electronic Ligands For π-Electronimentioning

confidence: 99%

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First decade of π-electronic ion-pairing assemblies

Haketa

Urakawa

Maeda

2020

Mol. Syst. Des. Eng.

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Section: -3 Metal Complexes Of π-Electronic Ligands For π-Electronimentioning

confidence: 90%

Section: -3 Metal Complexes Of π-Electronic Ligands For π-Electronimentioning

confidence: 99%

First decade of π-electronic ion-pairing assemblies

Haketa

Urakawa

Maeda

2020

Mol. Syst. Des. Eng.

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“…Porphyrins with metal ions in d 8 electronic configuration can function as charged π-electronic systems because they require no axial ligand coordination. On the basis of the synthesis strategy of charged π-electronic systems, we found that the porphyrin–Au III complexes and divalent metal complexes of oxophlorins (deprotonation states of meso -hydroxy-substituted porphyrins) , act as π-electronic cations and anions, respectively, for ion-pairing assemblies (Figure c). Porphyrin ion pairs can be obtained from various derivatives through peripheral modifications of the charged porphyrin skeletons, resulting in interesting electronic properties and functional materials.…”

Section: Introductionmentioning

confidence: 99%

π-Stacked Ion Pairs: Tightly Associated Charged Porphyrins in Ordered Arrangement Enabling Radical-Pair Formation

et al. 2022

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π-Electronic ion pairs are of interest for fabricating electronic materials that use intermolecular interactions based on electrostatic and dispersion forces, defined as i π− i π interactions, to provide dimension-controlled assemblies. Porphyrin ions, whose charge is delocalized in the core units, are suitable for ordered arrangement and assemblies by ion pairing. Herein, charged porphyrins were found to form solid-state assemblies and solution-state stacked ion pairs according to the peripheral electron-donating groups (EDGs) and electron-withdrawing groups (EWGs). The concentration-dependent 1 H NMR signal shifts of a porphyrin ion pair, comprising a meso-EWG cation and a meso-EWG anion, provided a hetero-dimerization constant of 2.8 × 10 5 M −1 in CD 2 Cl 2 at 20 °C. In the ion pair of a meso-EWG cation and a meso-EDG anion, the electron transfer in the steady and excited states according to solvent polarity and photoexcitation, respectively, produced the radical pairs. The electron spin resonance analysis in frozen toluene revealed the formation of a heterodiradical in a closely stacked structure by the antiferromagnetic dipolar interaction and temperature-dependent spin transfer behavior.

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“…The meso ‐substituents of porphyrin–Au III complexes are also important for controlling the ion‐pairing assembled structures. Porphyrin–Au III complexes that are partially substituted with meso ‐pentafluorophenyl units, including 5,10,15‐trisubstituted 1 b + , display the electron‐deficient properties and solid‐state columnar structures, depending on substitution patterns . Single‐crystal X‐ray analysis of the ion pair 1 b + ‐ 2 c ⋅Cl − reveals a solid‐state ion‐pairing assembly .…”

Section: Figurementioning

confidence: 99%

“…A two‐by‐two charge‐by‐charge columnar structure is observed (Figure b,c), in which dimeric stacking of 1 b + has a stacking distance of 3.25 Å between the porphyrin mean planes (Figure d). This dimeric structure is also observed in the solid states of 1 b + ‐Cl − and 1 b + ‐PF 6 − , wherein two 1 b + are stacked in reversed orientation, cancelling the dipole moments . The Cl − ⋅⋅⋅Cl − distance in the column is 3.98 Å (Figure a), suggesting that the electrostatic repulsion between two Cl − can be overcome by hydrogen‐bonding and electrostatic interactions between 2 c 2 ⋅Cl − 2 with two 1 b + , as revealed by the ESP diagram calculated at B3LYP/6‐31+G(d,p) with LanL2DZ for Au based on the crystal structure .…”

Section: Figurementioning

confidence: 99%

Ion‐Pairing Assemblies of Porphyrin–Au^III Complexes in Combination with π‐Electronic Receptor–Anion Complexes

Tanaka

Haketa

Bando

et al. 2020

Chemistry An Asian Journal

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Anion complexes of anion‐responsive π‐electronic molecules can behave as pseudo π‐electronic anions providing various ion pairs in combination with countercations. In this study, single crystals of ion‐pairing assemblies comprising porphyrin–AuIII complexes and Cl− complexes of dipyrrolyldiketone BF2 complexes were prepared from 1:1 mixtures of anion receptors and the Cl− salts of cationic porphyrins in solution. In the solid state, the ion pairs formed characteristic assemblies, depending on the substituents of the anion receptors and porphyrin–AuIII complexes. Theoretical calculations on the ion pairs revealed that the stacking structures are stabilized by compensating positive and negative charges as well as π–π interactions.

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Substitution‐Pattern‐ and Counteranion‐Depending Ion‐Pairing Assemblies Based on Electron‐Deficient Porphyrin–Au^III Complexes

Cited by 16 publications

References 26 publications

First decade of π-electronic ion-pairing assemblies

First decade of π-electronic ion-pairing assemblies

π-Stacked Ion Pairs: Tightly Associated Charged Porphyrins in Ordered Arrangement Enabling Radical-Pair Formation

Ion‐Pairing Assemblies of Porphyrin–Au^III Complexes in Combination with π‐Electronic Receptor–Anion Complexes

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Substitution‐Pattern‐ and Counteranion‐Depending Ion‐Pairing Assemblies Based on Electron‐Deficient Porphyrin–AuIII Complexes

Cited by 16 publications

References 26 publications

First decade of π-electronic ion-pairing assemblies

First decade of π-electronic ion-pairing assemblies

π-Stacked Ion Pairs: Tightly Associated Charged Porphyrins in Ordered Arrangement Enabling Radical-Pair Formation

Ion‐Pairing Assemblies of Porphyrin–AuIII Complexes in Combination with π‐Electronic Receptor–Anion Complexes

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Product

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Substitution‐Pattern‐ and Counteranion‐Depending Ion‐Pairing Assemblies Based on Electron‐Deficient Porphyrin–Au^III Complexes

Ion‐Pairing Assemblies of Porphyrin–Au^III Complexes in Combination with π‐Electronic Receptor–Anion Complexes