Harnessing Carbene Reactivity through Metallaphotoredox α-Elimination: A Versatile Approach to Complex Molecule Synthesis

Metallaphotoredox-enabled α-elimination provides a general strategy to access reactive carbene intermediates from readily available feedstocks, enabling diverse carbene-mediated transformations for complex molecule synthesis.

The content discusses a novel approach to accessing high-energy carbene intermediates, which are valuable but often challenging to generate using classical methods. The key innovation is a metallaphotoredox platform that enables carbene formation through a two-step radical addition and redox-promoted α-elimination process. The authors demonstrate the versatility of this strategy by showcasing its application to a range of carbene-mediated transformations, including cyclopropanation and σ-bond insertion into N–H, S–H, and P–H bonds. Importantly, these reactions can be carried out using abundant and bench-stable starting materials such as carboxylic acids, amino acids, and alcohols, overcoming the limitations of traditional carbene generation methods. The content highlights how this metallaphotoredox approach represents a general solution to the challenge of harnessing carbene reactivity for complex molecule synthesis, enabling the construction of diverse molecular scaffolds from readily available feedstocks.

Carbenes and carbenoid intermediates are particularly attractive, but often elusive, high-energy intermediates. Classical methods to access metal carbene intermediates often have prohibitive reagent safety concerns, limiting their broad implementation in synthesis. The metallaphotoredox platform enables carbene formation through a two-step radical addition and redox-promoted α-elimination process. The strategy is demonstrated for diverse carbene-mediated transformations, including cyclopropanation and σ-bond insertion into N–H, S–H, and P–H bonds.

"The ability to tame high-energy intermediates is critical for synthetic chemistry, enabling the construction of complex molecules and propelling advances in the field of synthesis." "Mechanistically, an alternative approach to carbene intermediates that could circumvent these pitfalls would involve two single-electron steps: radical addition to a metal to forge the initial carbon–metal bond followed by redox-promoted α-elimination to yield the desired metal carbene intermediate."