Abstract

Abstract This paper gives a general overview of several approaches we have investigated for designing new PLA-based polymers with a broad range of properties and improved processability. These approaches include: copolymerization (block and stereoblock copolymers), microstructure and architecture control, and stereocomplexation. Multiblock copolymers with alternating "soft" and "hard" segments, synthesized over a broad range of chemical compositions, show properties ranging from hard plastics to elastomers. Stereoblock copolymers with alternating amorphous and semicrystalline PLA blocks combine the advantages of PLA homopolymers (crystallinity) and random copolymers (processability). Independent control of polymer architecture and microstructure allows for the synthesis of star polymers with various arm morphologies. A new method for stereocomplex formation between L-PLA and D-PLA, which combines in-situ polymerization with stereocomplexation, is also described. For the synthesis of these new materials we took advantage of: 1) chirality of lactide monomer, 2) retention of configuration during polymerization, 3) living nature of the ring-opening polymerization (ROP) of lactide in the presence of active hydrogen groups such as OH and NH2, and 4) control of the level of transesterification reactions.