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Programmable 3D Shape-Change Liquid Crystalline Elastomer Based on a Vertically Aligned Monodomain with Cross-link

Jun Hu1, Ze-Yang Kuang1, Lei Tao1

  • 1Key Lab of Environment-friendly Chemistry and Application in Ministry of Education, and Key Laboratory of Advanced Functional Polymer Materials of Colleges, Universities of Hunan Province and College of Chemistry , Xiangtan University , Xiangtan , Hunan 411105 , China.

ACS Applied Materials & Interfaces
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PubMed
Summary

This study introduces a novel method for creating 3D shape-changing actuators using gradient cross-linked liquid crystalline elastomers (LCEs). These actuators exhibit remarkable bendability and complex deformations for advanced applications.

Keywords:
bending deformationgradient cross-linkingliquid crystalline elastomermicrowalkerstimuli-responsive materialsvertical alignment

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Area of Science:

  • Materials Science
  • Polymer Chemistry
  • Nanotechnology

Background:

  • Liquid crystalline elastomers (LCEs) are stimuli-responsive materials capable of 3D shape changes.
  • Existing LCEs typically exhibit homogeneous alignment, leading to linear shape changes like extension or contraction.
  • Developing LCEs with controlled, complex shape-changing capabilities is crucial for advanced actuator design.

Purpose of the Study:

  • To develop a simple and robust method for preparing 3D shape-change actuators based on gradient cross-linking of vertically aligned liquid crystals (LCs).
  • To investigate the relationship between cross-link gradient and the resulting mechanical properties and deformation behavior of LCE films.
  • To demonstrate the potential for creating complex 3D deformations and light-fueled actuators using patterned LCE films.

Main Methods:

  • Grafting gold nanoparticles onto liquid crystalline polymers (LCPs) to induce homeotropic orientation of LC monomers and cross-linkers.
  • Photopolymerization under UV irradiation to create LCE films with a controlled cross-link gradient.
  • Nanoindentation experiments to analyze the mechanical properties and Young's modulus distribution.
  • Fabrication of patterned LCE films and doping with multiwalled carbon nanotubes (CNTs) for specific functionalities.

Main Results:

  • Vertically aligned LCE films with a cross-link gradient were successfully prepared.
  • The gradient cross-linking resulted in excellent bendability under thermal stimulus, unlike typical LCEs.
  • Nanoindentation confirmed that the differential Young's modulus across the film thickness drives the deformation.
  • Scissoring and photomask patterning enabled precise control over bending angles and complex 3D deformations (bend, fold, buckle).
  • Patterned LCE films doped with CNT-PDB demonstrated light-fueled microwalker behavior with rapid crawling.

Conclusions:

  • Gradient cross-linking of vertically aligned LCEs provides a versatile platform for creating tunable 3D shape-changing actuators.
  • The developed method allows for precise control over deformation modes, from simple bending to complex folding and buckling.
  • The integration of CNTs opens possibilities for light-responsive actuators with advanced locomotion capabilities.