<p>Liquid crystal elastomers are unique choices for designing the next generation soft robots. Their synthesis relies exclusively on the polymerization/crosslinking of reactive mesogens with high molecular rigidity, necessitating high energy input to disrupt the molecular order for their actuation function. We report a non-mesogenic route towards designing liquid crystal elastomers. The monomeric precursors are non-mesogenic, but the supramolecular interactions are amplified in the polymerized network due to their cooperative nature, leading to liquid crystallinity. This allows resolving the common conflict between high actuation strain and low energy input, making it possible to design soft robots that can operate autonomously by harnessing the serendipitous energy from natural environments. Our molecular design broadens the scope of liquid crystalline materials, with potential implications beyond elastomeric actuators.</p>

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A supramolecular non-mesogenic route towards autonomous liquid crystal elastomer soft robots

  • Changfei He,
  • Yufan Yang,
  • Hong Wan,
  • Ning Zheng,
  • Yibao Li,
  • Tao Xie

摘要

Liquid crystal elastomers are unique choices for designing the next generation soft robots. Their synthesis relies exclusively on the polymerization/crosslinking of reactive mesogens with high molecular rigidity, necessitating high energy input to disrupt the molecular order for their actuation function. We report a non-mesogenic route towards designing liquid crystal elastomers. The monomeric precursors are non-mesogenic, but the supramolecular interactions are amplified in the polymerized network due to their cooperative nature, leading to liquid crystallinity. This allows resolving the common conflict between high actuation strain and low energy input, making it possible to design soft robots that can operate autonomously by harnessing the serendipitous energy from natural environments. Our molecular design broadens the scope of liquid crystalline materials, with potential implications beyond elastomeric actuators.