Addressing Charge‐Transfer and Locally‐Excited States in a Twisted Biphenyl Push‐Pull Chromophore

Campioli, Elisa; Sanyal, Somananda; Marcelli, Agnese; Donato, Mariangela Di; Blanchard‐Desce, Mireille; Mongin, Olivier; Painelli, Anna; Terenziani, Francesca

doi:10.1002/cphc.201900703

Cited by 15 publications

(15 citation statements)

References 62 publications

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“…We also recorded steady‐state fluorescence emission spectra (Figure 4) to investigate the occurrence of dual fluorescence to probe for the ICT/‐H‐bonding hypothesis. We would expect fluorescence from the LE and CT states [26] . Experimentally, the following was observed: all derivatives showed weak fluorescence signals in general.…”

Section: Resultsmentioning

confidence: 77%

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Selective Modification for Red‐Shifted Excitability: A Small Change in Structure, a Huge Change in Photochemistry

Becker

Roth

Scheurer³

et al. 2020

Chemistry A European J

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We developed three bathochromic, green‐light activatable, photolabile protecting groups based on a nitrodibenzofuran (NDBF) core with D‐π‐A push–pull structures. Variation of donor substituents (D) at the favored ring position enabled us to observe their impact on the photolysis quantum yields. Comparing our new azetidinyl‐NDBF (Az‐NDBF) photolabile protecting group with our earlier published DMA‐NDBF, we obtained insight into its excitation‐specific photochemistry. While the “two‐photon‐only” cage DMA‐NDBF was inert against one‐photon excitation (1PE) in the visible spectral range, we were able to efficiently release glutamic acid from azetidinyl‐NDBF with irradiation at 420 and 530 nm. Thus, a minimal change (a cyclization adding only one carbon atom) resulted in a drastically changed photochemical behavior, which enables photolysis in the green part of the spectrum.

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Section: Resultsmentioning

confidence: 77%

“…We would expect fluorescencef rom the LE and CT states. [26] Experimentally,t he following was observed:a ll derivatives showedw eak fluorescence signals in general.T his corresponds to our TDDFT calculations, which predicted low-energy transitions to the first excited states. Therefore, non-radiative decay is very likely.…”

Section: Resultsmentioning

confidence: 93%

Selective Modification for Red‐Shifted Excitability: A Small Change in Structure, a Huge Change in Photochemistry

Becker

Roth

Scheurer³

et al. 2020

Chemistry A European J

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“…Fast solvation then introduces a two-electron term in the electronic Hamiltonian, that however, in ESM acquires a very simple form with a clear physical meaning. Indeed for all CT dyes discussed here, with dipolar, quadrupolar or octupolar structure, one findsˆ µ 2 = µ 2 0ρ , so that H AA = H mol − elρ (9) where el = µ 2 0 r el /2 measures the amount of energy gained by the system in a zwitterionic state due the relaxation of the electronic clouds of the solvent molecule. In other terms, when going from gas phase to solution, the energy 2z required to separate a charge along a molecular arm is reduced by the solvent relaxation energy related to fast solvation, so that z → z − el /2.…”

Section: The Modelmentioning

confidence: 99%

“…The effective design of molecular materials for innovative applications requires the concurrent optimization of the active specie, the dye, and its matrix, a highly non trivial task, since the molecular properties depend, in an intrinsically non-linear way, from the properties of the local environment. Charge transfer (CT) dyes composed of electron-donor (D) and acceptor (A) moieties connected by π-conjugated bridges find applications in solar cells, 1 OLED, 2,3 non-linear optics, [4][5][6][7] and are interesting model systems for photoinduced CT. 8,9 The presence of low-lying excited states and of delocalized electrons makes these molecules extremely responsive to the local environment. 10 Intermolecular interactions in aggregates, supramolecular complexes and crystals have been discussed in different contexts, underlying how mutually interacting polarizable and/or polar molecules lead to specific spectroscopic features that cannot be reconciled with the standard exciton models.…”

Section: Introductionmentioning

confidence: 99%

Optical spectra of organic dyes in condensed phases: the role of the medium polarizability

Huu

Sissa

Terenziani

et al. 2020

Phys. Chem. Chem. Phys.

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“…Recently theoretical and experimental studies have contributed to the description of the structure-function relationships in push-pull systems with respect to solvent effects on the ICT dynamics [7,29,31,33].…”

Section: Study Of the Photophysical Properties And Excited State Dynamentioning

confidence: 99%

Synergistic Approach of Ultrafast Spectroscopy and Molecular Simulations in the Characterization of Intramolecular Charge Transfer in Push-Pull Molecules

et al. 2020

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The comprehensive characterization of Intramolecular Charge Transfer (ICT) stemming in push-pull molecules with a delocalized π-system of electrons is noteworthy for a bespoke design of organic materials, spanning widespread applications from photovoltaics to nanomedicine imaging devices. Photo-induced ICT is characterized by structural reorganizations, which allows the molecule to adapt to the new electronic density distribution. Herein, we discuss recent photophysical advances combined with recent progresses in the computational chemistry of photoactive molecular ensembles. We focus the discussion on femtosecond Transient Absorption Spectroscopy (TAS) enabling us to follow the transition from a Locally Excited (LE) state to the ICT and to understand how the environment polarity influences radiative and non-radiative decay mechanisms. In many cases, the charge transfer transition is accompanied by structural rearrangements, such as the twisting or molecule planarization. The possibility of an accurate prediction of the charge-transfer occurring in complex molecules and molecular materials represents an enormous advantage in guiding new molecular and materials design. We briefly report on recent advances in ultrafast multidimensional spectroscopy, in particular, Two-Dimensional Electronic Spectroscopy (2DES), in unraveling the ICT nature of push-pull molecular systems. A theoretical description at the atomistic level of photo-induced molecular transitions can predict with reasonable accuracy the properties of photoactive molecules. In this framework, the review includes a discussion on the advances from simulation and modeling, which have provided, over the years, significant information on photoexcitation, emission, charge-transport, and decay pathways. Density Functional Theory (DFT) coupled with the Time-Dependent (TD) framework can describe electronic properties and dynamics for a limited system size. More recently, Machine Learning (ML) or deep learning approaches, as well as free-energy simulations containing excited state potentials, can speed up the calculations with transferable accuracy to more complex molecules with extended system size. A perspective on combining ultrafast spectroscopy with molecular simulations is foreseen for optimizing the design of photoactive compounds with tunable properties.

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Addressing Charge‐Transfer and Locally‐Excited States in a Twisted Biphenyl Push‐Pull Chromophore

Cited by 15 publications

References 62 publications

Selective Modification for Red‐Shifted Excitability: A Small Change in Structure, a Huge Change in Photochemistry

Selective Modification for Red‐Shifted Excitability: A Small Change in Structure, a Huge Change in Photochemistry

Optical spectra of organic dyes in condensed phases: the role of the medium polarizability

Synergistic Approach of Ultrafast Spectroscopy and Molecular Simulations in the Characterization of Intramolecular Charge Transfer in Push-Pull Molecules

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