Germylium Catalyzed Dehydrofluorination Reactions of Fluorinated Alkanes

ABSTRACT

Lewis acidic compounds such as germylium ions can be applied to C─F bond activations to access fluorinated building blocks or degrade fluorinated alkyl compounds in order to address environmental concerns and to promote a circular economy. Germylium ions [R ₃ Ge][B(C ₆ F ₅ ) ₄ ] (R = Et, n Bu, and Ph) were isolated after treatment of [Ph ₃ C][B(C ₆ F ₅ ) ₄ ] with tertiary germanes. Derivatization reactions include the formation of binuclear fluoronium ions [R ₃ Ge–F–GeR ₃ ][B(C ₆ F ₅ ) ₄ ] (R = Et, n Bu, Ph) or fluorogermanes R ₃ GeF (R = Et, n Bu, Ph) after reaction with CsF. Various Lewis pairs such as [ n Bu ₃ Ge–PPh ₃ ][B(C ₆ F ₅ ) ₄ ] were also generated. The strong Lewis acidity of the germylium ions enables the C─F bond dehydrofluorination of mono‐ and polyfluorinated substrates. Thus, fluorocyclohexane was selectively converted into cyclohexene along with the production of H ₂ and fluorogermane. DFT calculations and experimental investigations revealed a concerted E2‐type mechanism where the tertiary germane reacts as a base to generate the olefinic products. The reaction pathway is in kinetic competition with an also concerted S _N 2‐type hydrodefluorination step. In contrast, the analogous silylium‐based reactions occur via a step‐wise S _N 1 mechanism, with the silane acting as a hydride donor to a fluorosilane‐stabilized carbenium ion leading exclusively to the thermodynamically favoured hydrodefluorination product.