Elementary Steps in Excited-State Proton Transfer

Agmon, Noam

doi:10.1021/jp047465m

Cited by 538 publications

(787 citation statements)

References 178 publications

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“…The substantial isotopic effect, τ D /τ H ∼ 1.4, observed in methanol, strongly points to the occurrence of reversible intermolecular proton transfer. 48,49 Such a process agrees with the increase of electron density at the nitro group in the S 1 state. Moreover, the occurrence of the H-bonding interaction was already suspected to be at the origin of the mirror image symmetry between absorption and emission spectra in protic solvents.…”

Section: Discussionsupporting

confidence: 79%

Excited-State Dynamics of Nitroperylene in Solution: Solvent and Excitation Wavelength Dependence

2008

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The photophysics and excited-state dynamics of nitroperylene (NPe) in solvents of various polarities and viscosities, including a room-temperature ionic liquid, have been investigated by femtosecond-resolved transient absorption spectroscopy. The excited-state absorption spectrum was found to depend substantially on solvent polarity. In the most polar solvents, it is very similar to that of the NPe radical cation generated upon bimolecular quenching by an electron acceptor, denoting a substantial charge-transfer character of the S 1 state. Contrary to smaller nitroaromatic compounds, NPe in the S 1 state does not undergo ultrafast intersystem crossing (ISC) but decays mainly by internal conversion (IC). In nonprotic solvents, IC involves low-frequency modes with large amplitude motion associated with the nitro group and depends on both the solvent viscosity and polarity. It takes place on a 100 ps time scale in acetonitrile, while in cyclohexane, it is slow enough for ISC to become competitive. Moreover, both the fluorescence quantum yield and the excited-state dynamics were found to differ, depending on which side of the S 0 -S 1 absorption band excitation was performed. This dependence is explained by the inhomogeneous nature of the absorption spectrum arising from a distribution of twist angles of the nitro group relative to the aromatic plane. On the other hand, such excitation wavelength effects were not observed in protic solvents, where the excited-state lifetime was found to be substantially shorter than that in nonprotic solvents. This behavior is rationalized in terms of a H-bonding interaction, which limits the torsional disorder of NPe and favors ultrafast nonradiative deactivation of the excited state. Transient absorption measurements performed for comparative purpose with nitropyrene in acetonitrile confirm the occurrence of ultrafast ISC in smaller nitroaromatic compounds.

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Section: Discussionsupporting

confidence: 79%

Excited-State Dynamics of Nitroperylene in Solution: Solvent and Excitation Wavelength Dependence

2008

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“…Such proton transfer often occurs along a pre-existing hydrogen bond and therefore becomes very fast, frequently on the ∼100 fs time scale or even faster. 36 ESPT to solvent has been studied for more than 60 years, 52,57,58 and many theoretical models have been proposed to describe various aspects of the transfer process, e.g. the dependence of transfer kinetics on solvent, temperature, pressure, deuterium substitution, complex formation, etc.…”

Section: ■ Discussionmentioning

confidence: 99%

Superior Photoprotective Motifs and Mechanisms in Eumelanins Uncovered

et al. 2014

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Human pigmentation is a complex phenomenon commonly believed to serve a photoprotective function through the generation and strategic localization of black insoluble eumelanin biopolymers in sun exposed areas of the body. Despite compelling biomedical relevance to skin cancer and melanoma, eumelanin photoprotection is still an enigma: What makes this pigment so efficient in dissipating the excess energy brought by harmful UV-light as heat? Why has Nature selected 5,6-dihydroxyindole-2-carboxylic acid (DHICA) as the major building block of the pigment instead of the decarboxylated derivative (DHI)? By using pico-and femtosecond fluorescence spectroscopy we demonstrate herein that the excited state deactivation in DHICA oligomers is 3 orders of magnitude faster compared to DHI oligomers. This drastic effect is attributed to their specific structural patterns enabling multiple pathways of intra-and interunit proton transfer. The discovery that DHICA-based scaffolds specifically confer uniquely robust photoprotective properties to natural eumelanins settles a fundamental gap in the biology of human pigmentation and opens the doorway to attractive advances and applications.

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“…The strong increase of fluorescence lifetime when going from H 2 O to D 2 O strongly supports the occurrence of this process. ESPT is a well-known quenching process of many aromatic ketones 45, 46 and has been reported with other aminonaphthalimide derivatives. 25 The ESPT hypothesis is further supported by a TCSPC experiment with a methanol solution in which a drop of LYen in DMSO had been added, which yielded (Fig.…”

Section: Steady-state and Nanosecond Photophysicsmentioning

confidence: 90%

Excited-state dynamics of the fluorescent probe Lucifer Yellow in liquid solutions and in heterogeneous media

Fürstenberg

Vauthey

2005

Photochem Photobiol Sci

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The photophysics of the dye Lucifer Yellow ethylenediamine (LYen) has been investigated in various polar solvents. The main deactivation pathways of its first singlet excited state are the fluorescence and the intersystem crossing. In water, non-radiative decay by intermolecular proton transfer becomes a significant deactivation channel. The early fluorescence dynamics, which was investigated in liquids and in reverse micelles, was found to depend substantially on the environment. An important static quenching of LYen by tryptophan and indole occurring in the subpicosecond timescale was observed. The use of the fluorescence dynamics of LYen as a local probe is illustrated by preliminary results obtained with a biotinylated Lucifer Yellow derivative complexed with avidin.

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Elementary Steps in Excited-State Proton Transfer

Cited by 538 publications

References 178 publications

Excited-State Dynamics of Nitroperylene in Solution: Solvent and Excitation Wavelength Dependence

Excited-State Dynamics of Nitroperylene in Solution: Solvent and Excitation Wavelength Dependence

Superior Photoprotective Motifs and Mechanisms in Eumelanins Uncovered

Excited-state dynamics of the fluorescent probe Lucifer Yellow in liquid solutions and in heterogeneous media

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