PHOTO-WALK was aimed to the utilization of photo-driven processes for the mild and selective functionalization of unactivated sp3 CH bonds. The initial plan was the use of readily available aliphatic amine derivatives as substates for the activation and functionalization at a remote site, triggering carboxylation, arylation and alkylation processes by merging photocatalysis and Ni-catalyzed cross-coupling. Subsequently, based on the knowledge acquired during the study of this transformations, we realized that a similar approach could be used to trigger a more challenging and conceptually intriguing activation and manipulation of another strong sp3 bond, an aliphatic CO bond. Such high challenging, yet high rewarding strategy allowed the development of two methods targeting diols derivatives, as cheap, abundant, and synthetically important molecules.
The first project tackled the challenge of using metallaphotoredox catalysis for the activation of strong sp3 CO bonds within the structure of a cyclic acetal, allowing the mild and site-selective arylation and alkylation of 1,n-diols (n ≥ 4) derivatives. The results of this project have been collected in a scientific paper and submitted to a high-ranked journal, thus a publication will appear soon. In addition, they will be presented and shared at an international conference in June 2022 (BIENAL2022, Granada, Spain).
The second project targeted the use of mono-protected 1,2-diols as precursors for the synthesis of aliphatic ketones, exploiting a spin-center shift (SCS) mechanism, which is currently unknown for aliphatic, acyclic systems. In this case, a purely photocatalytic method, characterized by exceptionally simple reaction conditions, allows the synthesis of complex ketone structure starting from mono-protected 1,2-diols per se or, upon a cascade reaction, triggers the modular construction of the carbon skeleton in situ. This approach shows the great potential to be extended to metallaphotoredox catalysis, including a Ni-catalyzed cross-coupling step to further improve the generality and modularity of the method, disclosing an appealing tool for building up molecular complexity. The generality of this strategy and its extension to the metallaphotoredox catalysis is currently under study.