Correlating Metal Redox Potentials to Co(III)K(I) Catalyst Performances in Carbon Dioxide and Propene Oxide Ring Opening Copolymerization |
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| Authors: | Dr. Wouter Lindeboom Dr. Arron C. Deacy Dr. Andreas Phanopoulos Prof. Antoine Buchard Prof. Dr. Charlotte K. Williams |
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| Affiliation: | 1. Department Chemistry, University of Oxford, Chemistry Research Laboratory, 12 Mansfield Road, Oxford, OX1 3TA UK;2. Department of Chemistry, Imperial College London, Molecular Sciences Research Hub, London, W12 OBZ UK;3. Department of Chemistry, Institute for Sustainability, University of Bath, Bath, BA2 7AY UK |
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| Abstract: | Carbon dioxide copolymerization is a front-runner CO2 utilization strategy but its viability depends on improving the catalysis. So far, catalyst structure-performance correlations have not been straightforward, limiting the ability to predict how to improve both catalytic activity and selectivity. Here, a simple measure of a catalyst ground-state parameter, metal reduction potential, directly correlates with both polymerization activity and selectivity. It is applied to compare performances of 6 new heterodinuclear Co(III)K(I) catalysts for propene oxide (PO)/CO2 ring opening copolymerization (ROCOP) producing poly(propene carbonate) (PPC). The best catalyst shows an excellent turnover frequency of 389 h−1 and high PPC selectivity of >99 % (50 °C, 20 bar, 0.025 mol% catalyst). As demonstration of its utility, neither DFT calculations nor ligand Hammett parameter analyses are viable predictors. It is proposed that the cobalt redox potential informs upon the active site electron density with a more electron rich cobalt centre showing better performances. The method may be widely applicable and is recommended to guide future catalyst discovery for other (co)polymerizations and carbon dioxide utilizations. |
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| Keywords: | Carbon Dioxide Catalysis Epoxide Ring Opening Copolymerization Structure-Activity |
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