Rejuvenating liquid crystal elastomers for self-growth

To date, only one polymer can self-grow to an extended length beyond its original size at room temperature without external stimuli or energy input. This breakthrough paves the way for significant advancements in untethered autonomous soft robotics, eliminating the need for the energy input or exter...

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Bibliographic Details
Published in:Nature communications 2024-08, Vol.15 (1), p.7381-9
Main Authors: Xu, Hongtu, Liang, Huan, Yang, Yang, Liu, Yawen, He, Enjian, Yang, Zhijun, Wang, Yixuan, Wei, Yen, Ji, Yan
Format: Article
Language:English
Subjects:
140/131
639/301/1005/1006
639/301/923/919
639/638/298/923/919
Bonding
Catalysts
Chemical bonds
Covalence
Covalent bonds
Crystal growth
Elastomers
External stimuli
Humanities and Social Sciences
Liquid crystals
multidisciplinary
Polymers
Robotics
Room temperature
Science
Science (multidisciplinary)
Soft robotics
Solvents
Stimuli
Swelling
Synergistic effect
Temperature requirements
Transesterification
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Summary:To date, only one polymer can self-grow to an extended length beyond its original size at room temperature without external stimuli or energy input. This breakthrough paves the way for significant advancements in untethered autonomous soft robotics, eliminating the need for the energy input or external stimuli required by all existing soft robotics systems. However, only freshly prepared samples in an initial state can self-grow, while non-fresh ones cannot. The necessity of synthesizing from monomers for each use imposes significant limitations on practical applications. Here, we propose a strategy to rejuvenate non-fresh samples to their initial state for on-demand self-growth through the synergistic effects of solvents and dynamic covalent bonds during swelling. The solvent used for swelling physically transforms the non-fresh LCEs from the liquid crystal phase to the isotropic phase. Simultaneously, the introduction of the transesterification catalyst through swelling facilitates topological rearrangements through exchange reactions of dynamic covalent bonds. The rejuvenation process can also erase growth history, be repeated several times, and be regulated by selective swelling. This strategy provides a post-modulation method for the rejuvenation and reuse of self-growing LCEs, promising to offer high-performance materials for cutting-edge soft growing robotics. To date, only one polymer can self grow to an extended length beyond its original size at room temperature without external stimuli or energy input paving the way for significant advancements in untethered autonomous soft robotics but only freshly prepared samples in an initial state can self-grow. Here, the authors propose a strategy to rejuvenate non-fresh samples to their initial state for on demand self-growth through the synergistic effects of solvents and dynamic covalent bonds during swelling.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-024-51544-x