Proton Catalysis in the Redox Responsivity of a Mini‐Sized Photochromic Diarylethene

Massaad, Julie; Micheau, J. C.; Coudret, Christophe; Serpentini, Charles Louis; Guirado, Gonzalo

doi:10.1002/chem.201301566

Cited by 12 publications

(12 citation statements)

References 54 publications

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“…The low oxidation potential value obtained for the carboxylate BIPS‐COO − derivative is due to the aromatic electron rich system of the indole moiety. Similar anodic peak potential values were observed for other aromatic electron rich heterocycles, such as thiophenecarboxylate derivatives [50] …”

Section: Resultssupporting

confidence: 81%

Electrocarboxylation of Spiropyran Switches through Carbon‐Bromide Bond Cleavage Reaction

et al. 2022

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This manuscript deals with carbon capture and utilization to synthetize high-added chemicals using CO 2 as a C1-organic building block for CÀ C bond formation. The study focuses on the electrocarboxylation of 1,3,3-trimethylindolino-6'-bromobenzopyrylospiran switch (Br-BIPS). Prior to the electrocarboxylation process, the electrochemical reduction mechanism of Br-BIPS and CO 2 is disclosed in polar aprotic solvents using two different cathodes (glassy carbon and silver) under nitrogen atmosphere. Once the role of the cathode in the reduction carbon-bromide bond cleavage is understood, carboxylated spiropyran derivatives can be synthesized in moderate yields and conversion rates through an electrocarboxylation process using CO 2 silver cathode and polar aprotic solvents. The "green" efficient route described in the current work would open a new sustainable strategy for designing and building "smart" surfaces with switchable physical properties.

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Section: Resultssupporting

confidence: 81%

Electrocarboxylation of Spiropyran Switches through Carbon‐Bromide Bond Cleavage Reaction

et al. 2022

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“…The pure diarylethene based RTILs ([ALIQUAT] 2 [DTE] and [P 6,6,6,14 ] 2 [DTE]) as thin films were prepared and studied by UV- ), involving first hydroxide anion exchange, followed by neutralization by means of an acid-base reaction using 1,2-bis(5'-carboxy-2'-methylthien-3'-yl)-cyclopentene. [29,30] [31] (313) 0.025 [31] (365) 1.44 [32] [o/o * + ] 0.85 [32] [c/c * + ] DTE 2À 0.67 [31] (313) 0.025 [31] (365) 0.87 [32] [o 2À /o * À ] 0.33 [32] [c 2À /c * À ] IL 1 0.23 [b] 2 [DTE] (colourless state) as pure RTILs showed two bands, one at shorter wavelengths as a well-defined peak at 258 nm followed by a small shoulder close to 300 nm. These results are similar to those obtained in solution (see supplementary information).…”

Section: Photochromic Room Temperature Ionic Liquids Based On Anionicmentioning

confidence: 99%

“…It is important to emphasize that in solution the photocyclization reaction is significantly faster compared to the RTIL. For several diarylethenes [2,33] and in particular for DTE, [31,32] formation of a by-product that diminishes the photochromic performance by affecting the photoswitching reversibility has been reported. Different approaches, such as varying the nature of the hetaryl moieties, the bridging units or the substituents, have been explored to suppress formation of this by-product and obtain highly fatigueresistance diarylethene-based photochromic systems.…”

Section: Photochromic Room Temperature Ionic Liquids Based On Anionicmentioning

confidence: 99%

Photochromic Room Temperature Ionic Liquids Based on Anionic Diarylethene Derivatives

et al. 2019

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Two photochromic room-temperature ionic liquids (RTILs) based on anionic diarylethene derivative (DTE) were synthesized and characterized. Photochemical (quantum yields for ring closure and opening) and electrochemical (cyclic voltammetry) properties of the [ALIQUAT] 2 [DTE] and [P 6,6,6,14 ] 2 [DTE] compounds as amorphous salts have been investigated. All compounds (including the di-acid precursor and two RTILs) were studied in solution, in their intrinsically pure forms (RTIL as unique media) and in the solid state (BaSO 4 support). Combination with larger organic cations can stabilize the closed-ring form, apparently avoiding the formation of by-products without photodegradation. It is observed that the closed-ring reaction is faster in the case of RTILs comparing to the di-acid starting material. The coloration switches between transparent (initial state) to purple ([ALIQUAT] 2 [DTE]) or pink ([P 6,6,6,14 ] 2 [DTE]). The novel diarylethene-based RTILs as multi-coloured photochromic materials can open attractive perspectives for materials science applications.

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“…The resulting charged defect V O 0 is lying in the middle of the band gap and is thought to be responsible in part for the observed visible emission by the recombination of the electron from the conduction band (CB) with the hole hosted in the V O 0 defect. 34,47 An electron transfer from the DTE's HOMO level (located at À5.9 eV and À5.2 eV for the open and closed isomer respectively) 48 towards V O 0 is thus energetically favorable. It was demonstrated previously that ZnO Ncs coated with dodecylamine can exchange electrons despite the presence of the ligand layer.…”

Section: Design Of the Photoswitchable Luminescent Systemmentioning

confidence: 99%

Photocontrol of luminescent inorganic nanocrystals via an organic molecular switch

Massaad

Coppel

Sliwa

et al. 2014

Phys. Chem. Chem. Phys.

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A photo-controlled and quasi-reversible switch of the luminescence of hexadecylamine-coated ZnO nanocrystals (ZnO@HDA Ncs) is operated via a molecular photoswitch (dithienylethene, DTE). The interaction between the DTE switch and the ZnO@HDA Ncs is thoroughly investigated using NMR spectroscopy techniques, including DOSY and NOESY, showing that the DTE switch is weakly adsorbed at the surface of the Ncs through the formation of hydrogen bonds with HDA. Steady state and time-resolved luminescence quenching experiments show a complex behavior, related to the spatial distribution of the emitting defects in the Ncs. Analysis of the data using models previously developed for Ncs supports static quenching. Both isomeric forms (open or closed) of the DTE switch quench the emission of Ncs, the efficiency being more than ten times higher for the closed isomer. The mechanism of quenching is discussed and we show that quenching occurs mainly through resonant energy transfer for the closed isomer and through electron transfer for the open one. The HDA layer mediates the quenching efficiency as only defects located near the surface are quenched.

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Proton Catalysis in the Redox Responsivity of a Mini‐Sized Photochromic Diarylethene

Cited by 12 publications

References 54 publications

Electrocarboxylation of Spiropyran Switches through Carbon‐Bromide Bond Cleavage Reaction

Electrocarboxylation of Spiropyran Switches through Carbon‐Bromide Bond Cleavage Reaction

Photochromic Room Temperature Ionic Liquids Based on Anionic Diarylethene Derivatives

Photocontrol of luminescent inorganic nanocrystals via an organic molecular switch

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