Convenient C(sp³)–H bond functionalisation of light alkanes and other compounds by iron photocatalysis

Abstract: A practical and green iron-catalyzed photoredox system for C–H functionalization of ethane, propane, and other light alkanes was developed.

“…Cl − →Cl⋅, E ox >+1.2 V vs SCE) with weakly oxidizing metals ( e. g . Cu 2+ →Cu + , E red =+0.50 V vs SCE; Fe 3+ →Fe 2+ , E red =+0.53 V vs SCE) can be achieved with this strategy [50,51] …”

Ligand‐to‐Metal Charge Transfer (LMCT) Photochemistry at 3d‐Metal Complexes: An Emerging Tool for Sustainable Organic Synthesis

“…Cl − →Cl⋅, E ox >+1.2 V vs SCE) with weakly oxidizing metals ( e. g . Cu 2+ →Cu + , E red =+0.50 V vs SCE; Fe 3+ →Fe 2+ , E red =+0.53 V vs SCE) can be achieved with this strategy [50,51] …”

Ligand‐to‐Metal Charge Transfer (LMCT) Photochemistry at 3d‐Metal Complexes: An Emerging Tool for Sustainable Organic Synthesis

“…Photoinduced ligand-to-metal charge transfer (LMCT) instead of traditional redox processes has proved to be an effective synthetic tool for constructing molecules. 10 Coordination of reactive functional groups with metal complexes enables chemoselective oxidation via direct excitation of metal–ligand complexes, generating reactive radical species to trigger a series of useful transformations, such as C–H functionalization, 11 β-scission, 12 and decarboxylative coupling reactions. 13 Among the transition metals utilized, iron is the most abundant one in the Earth's crust, and the photoactive nature of iron-substrate complexes provides ample opportunity to activate organic molecules and initiate the desired transformations via iron photoredox catalysis.…”

Iron-catalyzed ring-opening of cyclic carboxylic acids enabled by photoinduced ligand-to-metal charge transfer

“…Chemie Forschungsartikel decreased yields induced by TEMPO and BHT certified the inclusion of radical processes (entries 5 and 6). [24] According to the above investigations and reported literatures, a plausible mechanism for aerobic oxidative coupling of amines was proposed (Figure 3c). Initially, a PET between excited [PYTC + ]* and benzylamine gives a cationic radical PhCH 2 NH 2 * + and a reducing species.…”

Chromophore‐Inspired Design of Pyridinium‐Based Metal–Organic Polymers for Dual Photoredox Catalysis