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Catalytic Synergy Using Al(III) and Group 1 Metals to Accelerate Epoxide and Anhydride Ring-Opening Copolymerizations

Wilfred T. Diment, Georgina L. Gregory, Ryan W. F. Kerr, Andreas Phanopoulos, Antoine Buchard, Charlotte K. Williams

2021ACS Catalysis75 citationsDOIOpen Access PDF

Abstract

The controlled synthesis of polyesters via epoxide/anhydride ring-opening copolymerization is a versatile and generally applicable method to make many sustainable polymers, but catalyst activities are limited and the required catalyst loadings are typically high. Here, novel heterodinuclear complexes, featuring Al(III)/M(I) (M = Na, K, Rb, Cs), show exceptional activities for phthalic anhydride and cyclohexene oxide copolymerization (catalyst = Al(III)/K(I), turnover frequency = 1072 h–1, 0.25 mol % catalyst loading vs anhydride, 100 °C). The Al(III)/K(I) catalyst is also tolerant to low loadings, maintaining a good performance at 0.025 mol % catalyst vs anhydride loading and 0.005 mol % vs epoxide. It rapidly polymerizes other epoxide/anhydride combinations yielding various semi-aromatic, rigid, and/or functionalizable polyesters and also shows activity in carbon dioxide/epoxide copolymerizations. The results of structure–activity, X-ray crystallography, polymerization kinetics, and density functional theory investigations support a mechanism with chain growth alternation between the metals. The rate-limiting step is proposed to involve epoxide coordination at Al(III) with K(I) carboxylate attack. Future exploitation of abundant and inexpensive Group 1 metals to deliver synergic polymerization catalysts is recommended.

Topics & Concepts

EpoxidePhthalic anhydrideCatalysisCyclohexene oxidePolymerizationPolyesterCopolymerPolymer chemistryChemistryPropylene oxideSuccinic anhydridePolymerMaterials scienceOrganic chemistryEthylene oxideCarbon dioxide utilization in catalysisbiodegradable polymer synthesis and propertiesOrganometallic Complex Synthesis and Catalysis