The Key Role of Solvation Dynamics in Intramolecular Electron Transfer: Time-Resolved Photophysics of Crystal Violet Lactone

Schmidhammer, Uli; Megerle, Uwe; Lochbrunner, Stefan; Riedle, Eberhard; Karpiuk, Jerzy

doi:10.1021/jp800863u

Cited by 24 publications

(55 citation statements)

References 73 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…17 The solvent polarity dynamically determines the relative energetics of both CT states and controls the availability of the ET process and various deactivation pathways, thus effectively shaping the fluorescence spectrum displayed by CVL. 20 The ultrafast photoinduced ET process reversibly converting 1 CT A to 1 CT B occurs when the two states become temporarily isoenergetic which happens when the medium surrounding the molecule provides the energy stabilization required for the 1 CT B state down to the 1 CT A level, i.e., in solvents above certain threshold dielectric constant. The energies of the 1 CT B state in different media are essentially equal under isopolar conditions, and the same holds for 1 CT A .…”

Section: Resultsmentioning

confidence: 99%

“…3), is of essential importance for the threshold of medium dielectric constant required for appearance of the 1 CT B fluorescence, and conclusively, for the shape of the fluorescence spectrum displayed by CVL-like molecules, as lower DE requires lower e to stabilize 1 CT B to the energy equal to that of 1 CT A . 17,[19][20] DE can be changed by changing either the energy of 1 CT A or that of 1 CT B . The energy of the S 1 state in aminophthalides (i.e., of the 1 CT A state in a CVL-like structure) can be easily changed by modifying the substituent pattern at the amino nitrogen; taking 6-DMAPd as a reference, it is higher in 6-methylamino-and 6-aminophthalide and lower in aminophthalides with the amino group linked to an aromatic moiety by saturated six-membered rings.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Tuneable white fluorescence from intramolecular exciplexes

Karpiuk

Karolak

Nowacki

2010

Phys. Chem. Chem. Phys.

Self Cite

View full text Add to dashboard Cite

Crystal violet lactone (CVL) in solution displays unusually broad (FWHM > 9100 cm(-1)) dual fluorescence with the characteristics of white light. The emission combines a blue CT band from a local chromophore with an orange CT band from an intramolecular exciplex formed adiabatically at appropriate medium polarity. The fluorescence spectrum can be controlled by solvent polarity to yield tuneable emission colours in a broad range of coordinates in the CIE chromaticity diagram including the white region. We show that such dual emission is a general property of CVL-like D-A structures built on sp(3) carbon atoms. The dependence of excited state energetics on molecular structure allows the prediction of width, shape and other parameters of the dual fluorescence spectrum, and so enables the engineering and customised design of white fluorophores. The photophysics-structure relationship found for CVL and its analogues can be generalized into a novel concept of white light generation by small molecules. These D-A systems are studied as a template basis for design and development of white fluorophores.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Tuneable white fluorescence from intramolecular exciplexes

Karpiuk

Karolak

Nowacki

2010

Phys. Chem. Chem. Phys.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Such a solvent-controlled electron transfer has been documented in crystal violet lactone. [82] We believe that the radical pair state is best described as metastable. Once the ion pair state is accessed it is immediately lowered sufficiently that back electron transfer is highly unlikely.…”

Section: Discussionmentioning

confidence: 99%

A Comprehensive Microscopic Picture of the Benzhydryl Radical and Cation Photogeneration and Interconversion through Electron Transfer

et al. 2013

Self Cite

View full text Add to dashboard Cite

Bond cleavage and bond formation are central to organic chemistry. Carbocations play a key role in our understanding of nucleophilic substitution reactions that involve both processes. The precise understanding of the mechanism and dynamics of the photogeneration of carbocations and carbon radicals is therefore an important quest. In particular, the role of electron transfer for the generation of carbocations from the radical pair is still unclear. A quantitative femtosecond absorption study is presented, with ultrabroad probing on selected donor and acceptor substituted benzhydryl chlorides irradiated with 270 nm (35 fs) pulses. The ultrafast bond cleavage within 300 fs is almost exclusively homolytic, thus leading to a radical pair. The carbocations observable in the nanosecond regime are generated from these radicals by electron transfer from the benzhydryl to the chlorine radical within the first tens of picoseconds. Their concentration is reduced by geminate recombination within hundreds of picoseconds. In moderately polar solvents this depletion almost extinguishes the cation population; in highly polar solvents free ions are still observable on the nanosecond timescale. The explanation of the experimental findings requires the microscopic realm of the intermediates to be accounted for, including their spatial and environmental distributions. The distance dependent electron transfer described by Marcus theory is combined with Smoluchowski diffusion. The depletion of the radical pair distribution at small distances causes a temporal increase of the mean distance and the observed stretched exponential electron transfer. A close accord with experiment can only be reached for a broad distribution of the nascent radical pairs. The increase in the inter-radical and inter-ion pair distance is measured directly as a shift of the UV/Vis absorption of the products. The results demonstrate that, at least for aprotic solvents, traditional descriptions of reaction mechanisms based on the concept of contact and solvent-separated pairs have to be reassessed.

show abstract

“…The new frontier in ultrafast pump-probe spectroscopy is to extend the white light probe further into the UV and into the near IR as well as the kHz broadband detection of these continua with diode arrays or CCDs. These advancements give the spectroscopist broader and more unambiguous information about the dynamics of the system and hence aid in the interpretation of the complex mechanisms behind ultrafast chemical and physical processes [1,2]. In a first set of experiments on a flavine dissolved in methoxybenzyl alcohol we show the importance of continua ranging further into the UV and of the multichannel detection.…”

mentioning

confidence: 92%

New frontiers in ultrafast broadband pump-probe spectroscopy for the investigation of electron transfer processes

Pugliesi

Megerle

Bradler

et al. 2009

CLEO/Europe - EQEC 2009 - European Conference on Lasers and Electro-Optics and the European Quantum Electronics Conference

View full text Add to dashboard Cite

Time resolved pump-probe spectroscopy has experienced considerable improvements in the past two decades, especially with the advent of tunable femtosecond lasers such as noncollinear optical parametric amplifiers (NOPA). They allow for the selective excitation of chosen electronic transitions in molecular systems undergoing ultrafast photodynamics such as electron transfer. The new frontier in ultrafast pump-probe spectroscopy is to extend the white light probe further into the UV and into the near IR as well as the kHz broadband detection of these continua with diode arrays or CCDs. These advancements give the spectroscopist broader and more unambiguous information about the dynamics of the system and hence aid in the interpretation of the complex mechanisms behind ultrafast chemical and physical processes [1,2]. Fig. 1 Transient absorption spectra of (a) flavine and (b) Ph-NBI-Ph with different continua as probe. The middle spectra correspond to a range accessible by a Ti:Sa pumped sapphire continuum. In (a) the extension to the UV is accomplished via a CaF 2 continuum, in (b) the extension to the NIR is achieved with a 1100 nm pumped sapphire continuum. (VA: variable attenuator, WL: white light).In a first set of experiments on a flavine dissolved in methoxybenzyl alcohol we show the importance of continua ranging further into the UV and of the multichannel detection. After the flavine is photoexcited it becomes strongly oxidative and withdraws electrons from the alcohol. The associated electron transfer quenches the fluorescence of the flavine. A continuum generated with sapphire would only allow for the observation of the low picosecond components of this process mostly visible in the stimulated emission band between 500 and 600 nm. With a CaF 2 white light ranging down to 300 nm one can additionally observe the exited state absorption band between 320 and 400 nm (Fig. 1a). Its decay monitors the dynamics of the slower back electron transfer. Single channel time traces on this band yield strongly varying time constants due to the solvation induced spectral shift of the band. With multichannel detection, however, additional approaches like the evaluation of the band integral or global fits become possible. This leads to more reliable models of the photodynamics.In a second set of experiments we study the ultrafast electron transfer of a thiophenyl naphthalene bisimide (Ph-NBI-Ph). The transient spectra of Ph-NBI-Ph obtained with a continuum in the UV/Vis show a pronounced reshaping at picosecond times and complex multiexponential behavior. A model with two intermediate states has to be assumed with a fast electron transfer of 1 ps and two equal decay components of 6 ps. With a continuum that ranges further into the NIR it is possible to identify spectral signatures specific to the first intermediate and follow its dynamics separately (Fig 1b).In conclusion, these examples of electron transfer show that technical advancements in generating ultrabroad continua greatly simplify the unraveling of complex photorea...

show abstract

The Key Role of Solvation Dynamics in Intramolecular Electron Transfer: Time-Resolved Photophysics of Crystal Violet Lactone

Cited by 24 publications

References 73 publications

Tuneable white fluorescence from intramolecular exciplexes

Tuneable white fluorescence from intramolecular exciplexes

A Comprehensive Microscopic Picture of the Benzhydryl Radical and Cation Photogeneration and Interconversion through Electron Transfer

New frontiers in ultrafast broadband pump-probe spectroscopy for the investigation of electron transfer processes

Contact Info

Product

Resources

About