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Photoredox-controlled alternating copolymerization enables highly crystalline structures and block copolymers from thermoplastic to elastomer.


ABSTRACT: Ethylene-based crystalline copolymers are important materials across broad applications. However, precise control over their primary structures remains a critical challenge in advancing functional materials, limited by the intrinsic reactivity difference between ethylene and comonomers. In this work, we report the development of a light-driven organocatalyzed reversible-deactivation radical copolymerization to access well-defined ethylene-chlorotrifluoroethylene copolymer (ECTFE) under mild conditions (<5 atm, 25 °C). The rational design of a three-armed phenothiazine catalyst in combination with a fluorinated dithiocarbamate furnishes good chain-growth control in the photoredox-mediated copolymerization, yielding ECTFE of excellent alternating sequence with minimized chain defects, which resulted in high crystallinity and superior melting points (up to 263.8 °C). Importantly, the obtained ECTFE exhibits outstanding chain-end activity/fidelity, enabling chain-extension (co)polymerization to access a variety of unprecedented ECTFE-based block copolymers upon visible-light exposure, which has successfully integrated rigid and soft blocks in single chains. The ease of synthesizing such block copolymers creates a versatile and convenient platform to largely tune mechanical properties, affording polymeric materials spanning from thermoplastics to elastomers via structural tailoring.

SUBMITTER: Xu M 

PROVIDER: S-EPMC12783137 | biostudies-literature | 2025 Dec

REPOSITORIES: biostudies-literature

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Photoredox-controlled alternating copolymerization enables highly crystalline structures and block copolymers from thermoplastic to elastomer.

Xu Mengli M   Chen Qiankai Q   Han Shantao S   Chen Kaixuan K   Guo Xing X   Chen Mao M  

Nature communications 20251212 1


Ethylene-based crystalline copolymers are important materials across broad applications. However, precise control over their primary structures remains a critical challenge in advancing functional materials, limited by the intrinsic reactivity difference between ethylene and comonomers. In this work, we report the development of a light-driven organocatalyzed reversible-deactivation radical copolymerization to access well-defined ethylene-chlorotrifluoroethylene copolymer (ECTFE) under mild cond  ...[more]

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