Dehalogenation and Desulfonation from Aryl and Alkyl Compounds with a Cobalt Catalyst in the Presence of Alcohol

Reddy, Bhoomireddy Rajendra Prasad; Auffrant, Audrey; Gosmini, Corinne

doi:10.1002/ajoc.202100616

Cited by 5 publications

(2 citation statements)

References 55 publications

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“…On the other hand, alcohol is regarded as an ideal alternative hydrogen source due to its benign nature and easy operation. Only a few examples have been reported in transition metal‐catalyzed transfer hydro‐dehalogenation of halides with alcohols [6b,7c,8b,c,10b,12] . Among the alcohols, ethanol, as one of the most important alcohols, is abundant, sustainable, and environmentally friendly.…”

Section: Introductionmentioning

confidence: 99%

Manganese‐Catalyzed Transfer Hydrodebromination of Aryl Bromides with Ethanol

et al. 2023

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A convenient PNP pincer manganese catalyzed transfer hydrogenation of bromides to corresponding debrominated aryl compounds using ethanol as the hydrogen sources is reported. Importantly, the application of biomass-derived ethanol highlights the sustainability of the methodology. The use of 6phenyl substituted triazine-based P ipr N 5 P ipr manganese pincer catalyst allows for the debromination of various aryl bromides with good yields. Notably, the process also occurs with bromides derived from several classes of natural products and bioactive compounds, such as citronellol, diacetone fructose, cholesterol, and vitamin E.

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Section: Introductionmentioning

confidence: 99%

Manganese‐Catalyzed Transfer Hydrodebromination of Aryl Bromides with Ethanol

et al. 2023

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“…Halogenated organic compounds are a common class of environmental pollutants, and the reduction of C–halogen (C-X) bonds to C–H bonds is not only an important tool for detoxifying them but also a fundamental organic transformation in organic synthesis. − Although the ideal dehalogenation effect can be achieved by using highly reducible hydrated electronic or noble metal cocatalyst such as Pd or Rh, the cost is high. , Using solar energy as the driving force to reduce the C–X bond into a C–H bond can not only avoid the generation of harmful by-products but also alleviate the energy crisis. − At present, different types of photocatalysts have been used for the reduction of C-X bonds. For example, Zhao et al reported a composite material with Cu particles loaded on TiO 2 surface to co-catalyze polybrominated pollutants .…”

Section: Introductionmentioning

confidence: 99%

Rational Design of Electron Transfer Kineties of CdS/Zn(impim) Dots-on-Rods for Efficient Visible-Light Reduced C-X Bond

Feng

Ren

et al. 2023

ACS Appl. Mater. Interfaces

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Halogenated organic compounds are a kind of common environmental pollutants. Photocatalytic dehalogenation of C−halogen (C-X) bonds to C−H bonds can not only control environmental pollution but also realize important organic conversion reactions. However, the electron transfer kinetics of photocatalytic reduction of the C-X bond for semiconductor/MOF composites has remained unexplored. Herein, we successfully synthesized CdS/ Zn(impim) (MOF) dots-on-rods composite photocatalyst under mild conditions. Zn(impim) MOF consists of Zn(μ-N) 4 clusters and imidazole derivative ligands. Zn(impim), as a carrier, is beneficial to the dispersion of CdS nanoparticles and avoiding the agglomeration of CdS nanoparticles. The photocatalytic performance of CdS/Zn(impim) composites for the reduction of the C-X bond is much higher than that of pure CdS or Zn(impim). This high activity is due to the high electron separation efficiency of CdS assisted by Zn(impim). Under visible light irradiation, Zn(impim) is not excited due to its wide band gap of 3.26 eV. Through metal-to-ligand charge transfer of Zn(μ-N) 4 clusters, Zn(impim) accepts excited electrons from CdS because the Fermi energy level of CdS is more negative by Kelvin probe force microscopy. Moreover, fluorescence spectrum and femtosecond transient absorption spectroscopy reveal the related electron transfer kinetics in detail. In addition, the inherent porous structure of MOFs is beneficial to the adsorption of halogenated hydrocarbons, providing a suitable environment for the dehalogenation reaction, thus improving the activity. This work can further understand the electron transfer mechanism in semiconductor/MOF composites for photocatalytic halide dehalogenation.

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Frustrated Lewis pair-mediated hydro-dehalogenation: crucial role of non-covalent interactions

Mondal,

Chattaraj

2024

J Mol Model

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Dehalogenation and Desulfonation from Aryl and Alkyl Compounds with a Cobalt Catalyst in the Presence of Alcohol

Cited by 5 publications

References 55 publications

Manganese‐Catalyzed Transfer Hydrodebromination of Aryl Bromides with Ethanol

Manganese‐Catalyzed Transfer Hydrodebromination of Aryl Bromides with Ethanol

Rational Design of Electron Transfer Kineties of CdS/Zn(impim) Dots-on-Rods for Efficient Visible-Light Reduced C-X Bond

Frustrated Lewis pair-mediated hydro-dehalogenation: crucial role of non-covalent interactions

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