Arene C-H borylation strategy enabled by a non-classical boron cluster-based electrophile.
Sangmin KimJoseph W TreacyYessica A NelsonJordan A M GonzalezMilan GembickýKendall N HoukAlexander M SpokoynyPublished in: Nature communications (2023)
Introducing a tri-coordinate boron-based functional group (e.g., boronic ester) into an unactivated C-H bond in the absence of directing groups is an ongoing challenge in synthetic chemistry. Despite previous developments in transition metal-catalyzed and -free approaches, C-H borylation of sterically hindered arenes remains a largely unsolved problem to date. Here, we report a synthetic strategy of a two-step, precious metal-free electrophilic C-H borylation of sterically hindered alkyl- and haloarenes to generate aryl boronic esters. The first step relies on electrophilic aromatic substitution (EAS) induced by cage-opening of Cs 2 [closo-B 10 H 10 ], forming a 6-Ar-nido-B 10 H 13 product containing a B-C bond, followed by a cage deconstruction of arylated decaboranes promoted by diols. The combination of these two steps allows for the preparation of aryl boronic esters that are hardly accessible by current direct C-H borylation approaches. This reaction does not require any precious metals, highly-engineered ligands, pre-functionalized boron reagents, or inert conditions. In addition, the unique properties of a non-classical boron cluster electrophile intermediate, B 10 H 13 + , afford a regioselectivity with unique steric and electronic control without the undesirable side reactions.