Geometrical Effects on Intramolecular Quenching of Aromatic Ketone (π,π*) Triplets by Remote Phenolic Hydrogen Abstraction

Lathioor, Edward C.; Leigh, and William J.; Pierre, Michael J. St.

doi:10.1021/ja991207z

Cited by 30 publications

(33 citation statements)

References 73 publications

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“…Similar conclusions apparently also hold for the quenching of other triplet sensitizers like biacetyl [16] and flavin derivatives [17,18] by anisole, which prompted researchers to use anisole (derivatives) as low-reactivity reference systems for the chemistry of phenols. [19][20][21] While our own results for some BP derivatives are in accord with the charge-transfer mechanism in ACN solutions, we show herein that the reactivity of triplet excited BP towards anisole is dramatically dependent on the nature of the solvent. In particular, the reactivity of this system is dramatically enhanced in protic solvents and even reaches the reactivity of the well-documented BP/phenol system.…”

Section: Introductionsupporting

confidence: 77%

Efficient Photochemical Oxidation of Anisole in Protic Solvents: Electron Transfer driven by Specific Solvent–Solute Interactions

et al. 2010

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The dynamics of the bimolecular quenching of triplet excited benzophenone by anisole was studied by nanosecond flash photolysis. We carried out a detailed study of the solvent dependence of the reaction rates and efficiencies in a number of protic and non-protic solvents. These studies were augmented by theoretical modelling and experimental investigation of solute/solvent interactions in the triplet excited and the ground state, respectively. The triplet quenching that follows Stern-Volmer kinetics in all cases is profoundly dependent on the nature of the solvent, with the highest reactivity being consistently found in protic solvents. The results in non-protic solvents are compatible with unproductive quenching via a charge-transfer state, whereas the generally fast quenching in protic solvents is accompanied by efficient formation of free-radical products. Analysis of the solvent dependence in terms of Marcus theory reveals the impact of specific solvation of benzophenone by protic solvents on the ET driving force and kinetics. Specific solvation is found to support efficient free radical ion formation in media of moderate and low polarity as well.

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Section: Introductionsupporting

confidence: 77%

Efficient Photochemical Oxidation of Anisole in Protic Solvents: Electron Transfer driven by Specific Solvent–Solute Interactions

et al. 2010

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“…A recent photochemical study of molecules linking phenol with aromatic ketones showed that the intramolecular hydrogen bond between phenol and the excited triplet ketone induced an electron transfer followed by proton transfer. 45 In this mechanism, the contribution of the tunneling effect should be negligibly small.…”

Section: Resultsmentioning

confidence: 99%

Time-Resolved EPR Investigation of the Photo-initiated Intramolecular Antioxidant Reaction of Vitamin K−Vitamin E Linked Molecule

et al. 2001

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The models of vitamin K and vitamin E linked molecule, (1-(1,4-naphthoquinone-2-oxy)-6-(hydroxy-2,5,7,8-tetramethylchroman-2-carbonyloxy)-hexane), was synthesized as a model of vitamin K and vitamin E which coexist in biological membranes. The time-resolved EPR (TR-EPR) spectra of this molecule could be assigned to vitamin K and E radicals and showed that the excited triplet state of the vitamin K moiety was rapidly quenched by abstraction of hydrogen from the vitamin E moiety. The broad and emissive CIDEP spectra observed in ethanol suggested that the intramolecular interaction between vitamin K and vitamin E radicals was strong there. The relatively resolved spectra observed in a TX-100 micelle system, on the other hand, indicated that the interaction between these radicals was very weak. These results suggest that the vitamin K and E radicals existed around the water-oil interface of the micelle independently. The absence of a deuterium effect in our experiments showed that tunneling does not contribute significantly to the quenching reaction.

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“…The implications of the presence of such light-absorbing organics and the possible photochemical reactions are not yet well understood in the sea surface microlayer. But clearly, the presence of such photoactive compounds at the air/sea interfaces could give rise to photosensitized processes (Becker et al, 1995;Canonica et al, 2006Canonica et al, , 2000Canonica et al, , 2005Das et al, 1981;Ivanov et al, 2005;Lathioor and Leigh, 2001;Lathioor et al, 1999;Leigh et al, 1996) which may also affect chemistry in the marine boundary layer (MBL) (Reeser et al, 2008). Previously, we showed that chlorophyll may be a photochemical source of halogenated radicals or the driving force for ozone deposition at low wind speed (Clifford et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Photoinduced oxidation of sea salt halides by aromatic ketones: a source of halogenated radicals

et al. 2009

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Abstract.The interactions between triplet state benzophenone and halide anion species (Cl − , Br − and I − ) have been studied by laser flash photolysis (at 355 nm) in aqueous solutions at room temperature. The decay of the triplet state of benzophenone was followed at 525 nm. Triplet lifetime measurements gave rate constants, k q (M −1 s −1 ), close to diffusion controlled limit for iodide (∼8×10 9 M −1 s −1 ), somewhat less for bromide (∼3×10 8 M −1 s −1 ) and much lower for chloride (<10 6 M −1 s −1 ). The halide (X − ) quenches the triplet state; the resulting product has a transient absorption at 355 nm and a lifetime much longer than that of the benzophenone triplet state, is formed. This transient absorption feature matches those of the corresponding radical anion (X − 2 ). We therefore suggest that such reactive quenching is a photosensitized source of halogen in the atmosphere or the driving force for the chemical oxidation of the oceanic surface micro layer.

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Geometrical Effects on Intramolecular Quenching of Aromatic Ketone (π,π*) Triplets by Remote Phenolic Hydrogen Abstraction

Cited by 30 publications

References 73 publications

Efficient Photochemical Oxidation of Anisole in Protic Solvents: Electron Transfer driven by Specific Solvent–Solute Interactions

Efficient Photochemical Oxidation of Anisole in Protic Solvents: Electron Transfer driven by Specific Solvent–Solute Interactions

Time-Resolved EPR Investigation of the Photo-initiated Intramolecular Antioxidant Reaction of Vitamin K−Vitamin E Linked Molecule

Photoinduced oxidation of sea salt halides by aromatic ketones: a source of halogenated radicals

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