A comparative model for the chemisorption of CO was explored via three representative reaction pathways: carboxylation of cyclohexanone, carbonation of cyclohexanol, and carbamation of cyclohexylamine. The model substrates were activated using 1,8-diazabicyclo[5.4.0]undec-7-ene (DBU, an amidine superbase). For each of these reactions, the formation of the corresponding CO adducts was confirmed by C nuclear magnetic resonance and Fourier-transform infrared spectroscopy measurements. It was demonstrated that CO fixation occurred through either an enol-CO adduct (i.e. carboxylation), proton shuttling process (i.e. carbonation), or self-activation mechanism (i.e. carbamation). Volumetric adsorption measurements indicated that cyclohexanol was superior in its uptake capacity (11.7 mmol CO g sorbent) in comparison to cyclohexylamine (9.3 mmol CO g sorbent) or cyclohexanone (8.5 mmol CO g sorbent). As supported by density functional theory calculations, this trend was expected given the fact that the carbonation reaction proceeded through a more thermodynamically favorable reaction process.
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