Direct Measurement of Polymer-Chain-End-to-End Distances by Using RAFT Chain Transfer Agent as the FRET Acceptor.

Förster resonance energy transfer (FRET) is a powerful tool for measuring distances between two molecules (donor and acceptor) in close proximity (1-10 nm), which can be employed for determining polymer end-to-end distances (). However, previous works for labeling FRET pairs on chain-ends often involve relatively complex steps for materials preparation, potentially limiting their broad use in synthetic polymer systems. In this work, we introduce an anthracene-functionalized chain-transfer agent for reversible addition-fragmentation chain-transfer (RAFT) polymerizations, which can directly yield polymers containing FRET donor and acceptor molecules on respective chain-ends.

A Perspective on the History and Current Opportunities of Aqueous RAFT Polymerization.

Reversible addition-fragmentation chain transfer (RAFT) polymerization has proven itself as a powerful polymerization technique affording facile control of molecular weight, molecular weight distribution, architecture, and chain end groups - while maintaining a high level of tolerance for solvent and monomer functional groups. RAFT is highly suited to water as a polymerization solvent, with aqueous RAFT now utilized for applications such as controlled synthesis of ultra-high molecular weight polymers, polymerization induced self-assembly, and biocompatible polymerizations, among others. Water as a solvent represents a non-toxic, cheap, and environmentally friendly alternative to organic solvents traditionally utilized for polymerizations.

Recent Progress in Enhancing Poly(Lactic Acid) Stereocomplex Formation for Material Property Improvement.

The production and utilization of polymers have been widely implemented into diverse applications that benefit modern human society, but one of the most valuable properties of polymers, durability, has posed a long-standing environmental challenge from its inception since plastic waste can lead to significant contamination and remains in landfills and oceans for at least hundreds of years. Poly(lactic acid) (PLA) derived from renewable resources provides a sustainable alternative to traditional polymers due to its advantages of comparable mechanical properties with common plastics and biodegradability. However, the poor thermal and hydrolytic stability of PLA-based materials limit their potential for durable applications.