par Deldaele, Christopher 
;Michelet, Bastien ;Baguia, Hajar ;Kajouj, Sofia ;Romero, Eugénie ;Moucheron, Cécile ;Evano, Gwilherm
Référence Chimia, 72, page (621-629)
Publication Publié, 2018
;Michelet, Bastien ;Baguia, Hajar ;Kajouj, Sofia ;Romero, Eugénie ;Moucheron, Cécile ;Evano, Gwilherm Référence Chimia, 72, page (621-629)
Publication Publié, 2018
Article révisé par les pairs
| Résumé : | Organic transformations can broadly be classified into four categories including cationic, anionic, pericyclic and radical reactions. While the last category has been known for decades to provide remarkably efficient synthetic pathways, it has long been hampered by the need for toxic reagents, which considerably limited its impact on chemical synthesis. This situation has come to an end with the introduction of new concepts for the generation of radical species, photoredox catalysis – which simply relies on the use of a catalyst that can be activated upon visible light irradiation – certainly being the most efficient one. The state-of-the-art catalysts mostly rely on the use of ruthenium and iridium complexes and organic dyes, which still considerably limits their broad implementation in chemical processes: alternative readily available catalysts based on inexpensive, environmentally benign base metals are therefore strongly needed. Furthermore, expanding the toolbox of methods based on photoredox catalysis will facilitate the discovery of new light-mediated transformations. This article details the use of a simple copper complex which, upon activation with blue light, can initiate a broad range of radical reactions. |
