The mechanism originally proposed by Fischer and Tropsch for carbon monoxide (CO) hydrogenative catenation involves C-C coupling from a carbide-derived surface methylidene. A single molecular system capable of capturing these… Click to show full abstract
The mechanism originally proposed by Fischer and Tropsch for carbon monoxide (CO) hydrogenative catenation involves C-C coupling from a carbide-derived surface methylidene. A single molecular system capable of capturing these complex chemical steps is hitherto unknown. Herein, we demonstrate the sequential addition of proton and hydride to a terminal Mo carbide derived from CO. The resulting anionic methylidene couples with CO (1 atm.) at low-temperature (-78 °C) to release ethenone. Importantly, the synchronized delivery of two reducing equivalents and an electrophile, in the form of a hydride (H- = 2e- + H+), promotes alkylidene formation from the carbyne precur-sor and enables coupling chemistry, under conditions milder than previous described for single electron reduction steps. Thermodynamic measurements bracket the hydricity and acidity requirements for promoting methylidene formation from carbide as feasible upon heterogenolysis of H2. Methylidene formation prior to C-C coupling proves critical for organic product release, as evidenced by direct carbide carbonylation studies. Spectroscopic studies, a monosilylated model system, and Quantum Mechanics computations provide insight into the mechanistic details of this reaction sequence, which serves as a rare model of the initial stages of the Fischer Tropsch synthesis.
               
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