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Room-temperature autonomous self-healing glassy polymers with hyperbranched structure.


ABSTRACT: Glassy polymers are extremely difficult to self-heal below their glass transition temperature (T g) due to the frozen molecules. Here, we fabricate a series of randomly hyperbranched polymers (RHP) with high density of multiple hydrogen bonds, which show T g up to 49 °C and storage modulus up to 2.7 GPa. We reveal that the hyperbranched structure not only allows the external branch units and terminals of the molecules to have a high degree of mobility in the glassy state, but also leads to the coexistence of "free" and associated complementary moieties of hydrogen bonds. The free complementary moieties can exchange with the associated hydrogen bonds, enabling network reconfiguration in the glassy polymer. As a result, the RHP shows amazing instantaneous self-healing with recovered tensile strength up to 5.5 MPa within 1 min, and the self-healing efficiency increases with contacting time at room temperature without the intervention of external stimuli.

SUBMITTER: Wang H 

PROVIDER: S-EPMC7260978 | biostudies-literature | 2020 May

REPOSITORIES: biostudies-literature

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Room-temperature autonomous self-healing glassy polymers with hyperbranched structure.

Wang Hao H   Liu Hanchao H   Cao Zhenxing Z   Li Weihang W   Huang Xin X   Zhu Yong Y   Ling Fangwei F   Xu Hu H   Wu Qi Q   Peng Yan Y   Yang Bin B   Zhang Rui R   Kessler Olaf O   Huang Guangsu G   Wu Jinrong J  

Proceedings of the National Academy of Sciences of the United States of America 20200507 21


Glassy polymers are extremely difficult to self-heal below their glass transition temperature (T g) due to the frozen molecules. Here, we fabricate a series of randomly hyperbranched polymers (RHP) with high density of multiple hydrogen bonds, which show T g up to 49 °C and storage modulus up to 2.7 GPa. We reveal that the hyperbranched structure not only allows the external branch units and terminals of the molecules to have a high degree of mobility in the glassy state, but also leads to the c  ...[more]

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