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Abstract
CO2 reacts with simple amines in presence of water to generate dynamic combinatorial libraries of majority (i.e., am-monium carbamates) and minority (i.e., ammonium carbonates) non-isoenergetic covalent adducts. Over the past decade, our laboratory has reported a new class of cavitands, namely dyn[n]arenes, from which a polyanionic macro-cycle is an highly efficient receptor for linear poly-ammoniums to form [2]pseudorotaxanes in water at neutral pH. Herein, we demonstrate that this formation of [2]pseudorotaxanes shifts the equilibrium of CO2 capture by polyam-ines in water towards the quasi-exclusive formation of carbonate adducts, providing the first example of a switch between two competitive and reversible covalent processes triggered by host-guest interactions. In addition, this su-pramolecular approach to CO2 capture exhibits enhanced capture efficiency by increasing the state of protonation of complexed vs. uncomplexed polyamines. Altogether, we report here that a templating approach can divert the out-come of two reversible covalent chemistries involving nucleophilic additions and acid-base reactions, challenging therefore the common knowledge that non-covalent interactions are weaker bonds than covalent ones.
Supplementary materials
Title
Supporting Information
Description
General methods, thermodynamic models, sample preparation, 1H- and 13C-qNMR analyses, ITC experiments, and X-ray crystallography.
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