On the Coherent Description of Diffusion‐Influenced Fluorescence Quenching Experiments

Rosspeintner, Arnulf; Kattnig, Daniel R.; Angulo, Gonzalo; Landgraf, Stephan; Grampp, Günter; Cuetos, Alejandro

doi:10.1002/chem.200700106

Cited by 34 publications

(71 citation statements)

References 64 publications

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“…2 Experimental scrutiny of these theories is only now being performed. [3][4][5][6][7] It has been shown how the viscosity and the magnetic field modulate reactions. For example, it has been observed that recombination efficiency depends on the viscosity of the medium non-monotonically as a combined effect of the molecular transport and the spatial characteristics of the electron transfer reactions.…”

Section: Introductionmentioning

confidence: 99%

Influence of the excitation light intensity on the rate of fluorescence quenching reactions: pulsed experiments

Angulo

Milkiewicz

Kattnig

et al. 2017

Phys. Chem. Chem. Phys.

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The effect of multiple light excitation events on bimolecular photo-induced electron transfer reactions in liquid solution is studied experimentally. It is found that the decay of fluorescence can be up to 25% faster if a second photon is absorbed after a first cycle of quenching and recombination. A theoretical model is presented which ascribes this effect to the enrichment of the concentration of quenchers in the immediate vicinity of fluorophores that have been previously excited. Despite its simplicity, the model delivers a qualitative agreement with the observed experimental trends. The original theory by Burshtein and Igoshin (J. Chem. Phys., 2000, 112, 10930-10940) was created for continuous light excitation though. A qualitative extrapolation from the here presented pulse experiments to the continuous excitation conditions lead us to conclude that in the latter the order of magnitude of the increase of the quenching efficiency upon increasing the light intensity of excitation, must also be on the order of tens of percent. These results mean that the rate constant for photo-induced bimolecular reactions depends not only on the usual known factors, such as temperature, viscosity and other properties of the medium, but also on the intensity of the excitation light.

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Section: Introductionmentioning

confidence: 99%

Influence of the excitation light intensity on the rate of fluorescence quenching reactions: pulsed experiments

Angulo

Milkiewicz

Kattnig

et al. 2017

Phys. Chem. Chem. Phys.

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“…This program was successfully realized in a very recent paper [96]. The lack of information was filled in by relating the Stern-Volmer constant κ(c) to the DET rate constant, k A (t):…”

Section: Stern-volmer Constantmentioning

confidence: 99%

“…The obtained relationships between diffusion and viscosity, D(η), for the models (128) were shown to be very close to the StokesEinstein models for the stick and slip friction coefficient. Specifying D in this way, the authors of [96] …”

Section: Stern-volmer Constantmentioning

confidence: 99%

“…In fact, the authors of [96] tested 6 different models of k A (t) calculations (with and without accounting for g (r) and D(r)) and selected only two of them which account simultaneously for the liquid structure and the space dependence of D(r) (one or another). 150 experimental data points for κ(c, D) were obtained from the fluorescence quantum yield studied in the 8 solvents of different compositions (viscosities).…”

Section: Stern-volmer Constantmentioning

confidence: 99%

“…Besides, the hydrodynamic effect is taken into account, which results in the space dependence of the diffusion coefficient at short distances between reactants. This dependence is represented by the simple expressions taken from either the Northrup and Hynes or Deutch and Felderhof models [96]:…”

Section: Stern-volmer Constantmentioning

confidence: 99%

See 2 more Smart Citations

Contact and Distant Luminescence Quenching in Solutions

Burshteǐn

2009

Advances in Physical Chemistry

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The Rehm–Weller Experiment in View of Distant Electron Transfer

Rosspeintner

Kattnig

Angulo

et al. 2008

Chemistry A European J

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The driving-force dependence of bimolecular fluorescence quenching by electron transfer in solution, the Rehm-Weller experiment, is revisited. One of the three long-standing unsolved questions about the features of this experiment is carefully analysed here, that is, is there a diffusional plateau? New experimental quenching rates are compiled for a single electron donor, 2,5-bis(dimethylamino)-1,3-benzenedicarbonitrile, and eighteen electron acceptors in acetonitrile. The data are analysed in the framework of differential encounter theory by using an extended version of the Marcus theory to model the intrinsic electron-transfer step. Only by including the hydrodynamic effect and the solvent structure can the experimental findings be well modelled. The diffusional control region, the "plateau", reveals the inherent distance dependence of the reaction, which is shown to be a general feature of electron transfer in solution.

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On the Coherent Description of Diffusion‐Influenced Fluorescence Quenching Experiments

Cited by 34 publications

References 64 publications

Influence of the excitation light intensity on the rate of fluorescence quenching reactions: pulsed experiments

Influence of the excitation light intensity on the rate of fluorescence quenching reactions: pulsed experiments

Contact and Distant Luminescence Quenching in Solutions

The Rehm–Weller Experiment in View of Distant Electron Transfer

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