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Article Abstract
Living copolymerization of mixed monomers can enrich the diversity of copolymer materials with well-defined performance via controlling both monomers and stereosequences. However, periodic sequence-controlled living copolymerization of same-type monomers with more than two components in synthetic polymer science remains a challenge. In this work, a new method of monomer-promoting asymmetric kinetic resolution-alternating copolymerization can let a tricomponent mixture of l-lactide (-LA or l-LA) and two enantiomeric isomers of racemic tropic acid cyclic esters (tropicolactone) be polymerized into sequence-controlled -(AAB)- type biodegradable copolyesters (the subscript S presents the configuration and A and B present lactic acid units and tropic acid units, respectively), and diblock copolymers of -(AAB)--(AAB)- can further be obtained upon addition of -LA (dLA). Compared to previous asymmetric kinetic resolutions of racemic chemicals via polymerization or organic reactions, no enantiopure catalyst/initiator is required in this system. After the resolution and alternating copolymerization of -LA and -tropicolactone, the ee value of unreacted tropicolactone can reach 99.4%. The alternating probability between tropicolactone and lactide monomers is more than 96% in periodic sequence polymers of -(AAB)-. The tetracomponent mixture of -lactide and -tropicolactone can be copolymerized into an alternating copolymer with a -((AAB)--(AAB))- structure, in which the stereoselective linkage probability of 95% after ,-lactide (,lactide) followed by -tropicolactone (-tropicolactone) keeps very high too.
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| http://dx.doi.org/10.1021/jacs.3c01599 | DOI Listing |
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