Up to know, the developed iron methodologies (inter- and intra-molecular) for carbene insertion into C(sp3)-H bonds were limited to weak allylic, benzylic and adjacent to heteroatom C(sp3)-H bonds (BDE < 90 Kcal/mol), using a heme like iron (III) phtalocyanine catalysts, and laboratory evolved P-450 enzymes. Going beyond these rigid systems, we have developed an ortho-phenylenediamide iron compound of electrophilic nature, which in combination with a lithium salt, as Lewis acid, enables unprecedented iron catalyzed intra- and inter-molecular carbene insertion into a variety of non-activated aliphatic C-H bonds, via iron-carbene intermediates under mild conditions (25ºC). Remarkably this Fe/Li system exhibits activity and selectivity levels comparable to rhodium carboxylate catalysts.
The generated advances in the field are expected to have a major impact, appealing to the broad spectrum of synthetic chemists (organic, inorganic, organometallic, green) spanning both academia and industry, since a new atom-economical, sustainable, mild temperature and selective methodology for functionalising Csp3-H bonds has been achieved. Furthermore, considering that iron-mediated organic synthesis constitutes a hot topic, due to sustainability reasons, it is envisaged that these results will lead to high impact scientific results, with publication in high-ranking academic journals.