Visible Light‐Induced Intramolecular C─O Bond Formation via 1,5‐Hydrogen Atom Transfer Strategy

Abstract: An efficient strategy for the visible‐light‐promoted intramolecular C─O bond formation has been accomplished, which allows the synthesis of cyclic ether derivatives in the absence of a photocatalyst. This reaction is likely to occur through the generation of alkoxy radical from in situ generated O─I bond, followed by 1,5‐hydrogen atom transfer (1,5‐HAT) and subsequent intramolecular cyclization to form a C─O bond. This synthetic approach offers an efficient tool by providing access to valuable cyclic ether sca… Show more

“…Light energy can activate substrates and produce organic reactions under mild conditions [27,29] . Typically, photochemical methods are effectively used for reactions involving radical pathways to form C−C coupling or carbon‐heteroatom bonds [30–38] . However, photochemical reactions often require expensive photocatalysts such as complexes of Ir or Ru metals or dye compounds [39–42] .…”

Visible‐Light‐Driven Sulfonamidation of Arylazo Sulfonesthrough One‐Pot Multicomponent Reaction

“…Light energy can activate substrates and produce organic reactions under mild conditions [27,29] . Typically, photochemical methods are effectively used for reactions involving radical pathways to form C−C coupling or carbon‐heteroatom bonds [30–38] . However, photochemical reactions often require expensive photocatalysts such as complexes of Ir or Ru metals or dye compounds [39–42] .…”

Visible‐Light‐Driven Sulfonamidation of Arylazo Sulfonesthrough One‐Pot Multicomponent Reaction

“…HFIP (1,1,1,3,3,3-hexafluoroisopropanol) has been recognized as a “magical solvent” in organic synthesis for its remarkable ability associated with hydrogen bonding . Since its first synthesis by Knunyants, HFIP has been frequently chosen as an advantageous solvent or additive . With its strong hydrogen bonding ability, HFIP promotes functionalization of C–X, C–O, CO, CN, CC, and even C–H bonds with a metal catalyst, to form new C–C or C–N bonds effectively (Scheme ).…”

HFIP-Empowered One-Pot Synthesis of C4-Aryl-Substituted Tetrahydroquinolines with Propargylic Chlorides and Anilines

“…Prompted by the interest in the nitrogen-centered-radical based 1,5-HAT strategy, researchers recently have made remarkable contributions to remote C-H bond functionalization via nitrogen-centered-radical (NCR)-triggered radical translocation processes. These innovative approaches have enabled the formation of a diverse range of bonds, including the building of C-C, 13,20 C-O, 21,22 C-N, [23][24][25][26] C-S, 27 and C-X (X = halogen) bonds. 14,19,28 Owing to its abundance, minimal toxicity, and renewability, carbon dioxide (CO 2 ), the well-known greenhouse gas, emerges as an ideal one-carbon building block for the formation of C-C bonds in organic synthesis.…”

“…4,17–19 Prompted by the interest in the nitrogen-centered-radical based 1,5-HAT strategy, researchers recently have made remarkable contributions to remote C–H bond functionalization via nitrogen-centered-radical (NCR)-triggered radical translocation processes. These innovative approaches have enabled the formation of a diverse range of bonds, including the building of C–C, 13,20 C–O, 21,22 C–N, 23–26 C–S, 27 and C–X (X = halogen) bonds. 14,19,28…”

Photocarboxylation of remote C–H bonds through nitrogen-centred radical 1,5-hydrogen atom transfer