Developing efficient strategies to copolymerize carbon dioxide (CO2) with unsaturated hydrocarbon monomers, such as olefins, to produce CO2-based polyesters is highly desirable but remains challenging owing to thermodynamic and kinetic barriers. Herein, we demonstrate that allenes, specifically cyclohexylallene (CA), serve as effective comonomers for one-pot copolymerization with CO2. Using a nickel(0)-bidentate diarylphosphine complex, we achieve the statistical copolymerization of CA and CO2 to deliver long-chain polyester P(CA-co-CO2) with widely spaced ester linkages, via a classical sequence of oxidative addition, coordination-insertion, and reductive elimination. Systematic tuning of both phosphine ligand and solvent reveals their crucial roles in facilitating CO2 insertion into the Ni-C bond and subsequent allene insertion into the Ni-O bond, thereby driving efficient chain propagation. Notably, incorporation of a small amount of CO2 into the polymer backbone enhances the degradability of P(CA-co-CO2) while preserving its high thermal stability and glass-transition temperature, compared with the allene homopolymer.
Liao et al. (Thu,) studied this question.
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