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Abstract
In the modern era of organic synthesis, mechanisms centering on radical intermediates have become increasingly impact-ful in unlocking novel reactivity. Among all, hydrogen atom transfer (HAT) represents one of the most fundamental chemical reaction steps and has found applications in designing practical transformations. Herein, we present a detailed case study on selective hydrodefluorination of trifluoromethylarenes utilizing N-heterocyclic carbene boranes (NHC-boranes) as the HAT donor. Under the optimal conditions featuring an acridine-based photocatalyst, complete selectivity for mono-hydrodefluorination was achieved across a wide array of substrates. Comprehensive mechanistic studies com-bining experimental and computational approaches disproved a chain process involving a fluorine atom transfer but ra-ther pointed to a HAT non-chain mechanism, where the key step involves the difluorobenzylic radical abstracting a hy-drogen atom from the NHC-borane to generate a boryl radical in a polarity-matched fashion. Evaluation of a selection of Lewis base-ligated boranes revealed molecular descriptors critical to the outcomes of this reaction, and a classification model is built to explain the structure-reactivity relationship and how various elementary steps can be influenced. These results collectively provide valuable information for future reaction design to elevate the utility of boranes in organic radical chemistry.
