Stable Aromatic Dianion in Water

Shirman, Elijah; Ustinov, A. O.; Ben-Shitrit, Netanel; Weissman, Haim; Iron, Mark A.; Cohen, Revital; Rybtchinski, Boris

doi:10.1021/jp8029743

Cited by 107 publications

(127 citation statements)

References 41 publications

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“…Thus, the electrochemistry is strongly influenced by the aggregation modes. [10] The sharp peak in the case of 1 P is consistent with uniform structure and stronger electronic coupling resulting from extensive overlap of the aromatic moieties. Two distinct reduction peaks for 1 G point to a lesser degree of coupling and greater similarity to the individual molecules of 1.…”

Section: Tem (Seementioning

confidence: 65%

Hydrophobic Self‐Assembly Affords Robust Noncovalent Polymer Isomers

Baram¹,

Weissman²,

Tidhar³

et al. 2014

Angewandte Chemie

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In covalent polymerization, a single monomer can result in different polymer structures due to positional, geometric, or stereoisomerism. We demonstrate that strong hydrophobic interactions result in stable noncovalent polymer isomers that are based on the same covalent unit (amphiphilic perylene diimide). These isomers have different structures and electronic/photonic properties, and are stable in water, even upon prolonged heating at 100 8C. Such combination of covalent-like stability together with structural/functional variation is unique for noncovalent polymers, substantially advancing their potential as functional materials.

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Section: Tem (Seementioning

confidence: 65%

Hydrophobic Self‐Assembly Affords Robust Noncovalent Polymer Isomers

Baram¹,

Weissman²,

Tidhar³

et al. 2014

Angewandte Chemie

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“…[56] Likewise, serious electron mobility degradation was observed in PDI and fullerene derivatives for OFETs upon exposure to air. [59–61] This is a result of electron trapping by absorbed O 2 and water.…”

Section: Resultsmentioning

confidence: 99%

Highly Soluble Benzo[ghi]perylenetriimide Derivatives: Stable and Air‐Insensitive Electron Acceptors for Artificial Photosynthesis

et al. 2015

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A series of new benzo[ghi]perylenetriimide (BPTI) derivatives has been synthesized and characterized. These remarkably soluble BPTI derivatives show strong optical absorption in the range of λ=300–500 nm and have a high triplet-state energy of 1.67 eV. A cyanophenyl substituent renders BPTI such a strong electron acceptor (Ered=−0.11 V vs. the normal hydrogen electrode) that electron-trapping reactions with O2 and H2O do not occur. The BPTI radical anion on a fluorine-doped tin oxide|TiO2 electrode is persistent up to tens of seconds (t1/2=39 s) in air-saturated buffer solution. As a result of favorable packing, theoretical electron mobilities (10−2∼10−1 cm2 V−1 s−1) are high and similar to the experimental values observed for perylene diimide and C60 derivatives. Our studies show the potential of the cyanophenyl-modified BPTI compounds as electron acceptors in devices for artificial photosynthesis in water splitting that are also very promising nonfullerene electron-transport materials for organic solar cells.

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“…13 When stored under inert atmosphere, these chromophores are stable in organic or even aqueous solution. 14 A similar strategy, in which a reduced chromophore is used to sensitize a Re(bpy)(CO) 3 center, has been reported very recently by Neumann and co-workers in a system incorporating a reduced polyoxometalate as a long-wavelength-absorbing chromophore. 15 This method, in which a highly reducing chromophore is easily generated using chemical or electrochemical means and subsequently used to drive a highly endothermic electron transfer reaction, is applicable not only to the study of carbon-dioxide reduction, but could also be employed to facilitate other transformations such as photoelectrocatalytic N 2 reduction or photoredox reactions involving electron-rich organic substrates that are not easily reduced using typical photoredox chromophores.…”

Section: Introductionmentioning

confidence: 93%