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Abstract Shape‐switching behavior, where a transient stimulus induces an indefinitely stable deformation that can be recovered on exposure to another transient stimulus, is critical to building smart structures from responsive polymers as continue power is not needed to maintain deformations. Herein, we 4D‐print shape‐switching liquid crystalline elastomers (LCEs) functionalized with supramolecular crosslinks, dynamic covalent crosslinks, and azobenzene. The salient property of shape‐switching LCEs is that light induces long‐lived, deformation that can be recovered on‐demand by heating. UV‐light isomerizes azobenzene fromtranstocis, and temporarily breaks the supramolecular crosslinks, resulting in a programmed deformation. After UV, the shape‐switching LCEs fix more than 90 % of the deformation over 3 days by the reformed supramolecular crosslinks. Using the shape‐switching properties, we print Braille‐like actuators that can be photoswitched to display different letters. This new class of photoswitchable actuators may impact applications such as deployable devices where continuous application of power is impractical.
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Photoswitchable Liquid Crystal Elastomer Adhesives Operating at Room Temperature
The ability to toggle adhesion between two surfaces on demand using reusable “smart” plastics would enable a myriad of applications where two components require temporary bonding, such as in dry transfer of materials for electronics applications. To this end, light is an attractive stimulus owing to its modularity, low energy consumption, and spatiotemporal control. However, a lack of materials capable of reversible light-triggered adhesion at room temperature exists. Herein, a systematic examination of azobenzene-containing liquid crystal elastomers (LCEs) revealed design principles that relate processing and composition to the performance of photoswitchable adhesives. This led to LCEs capable of reversibly picking up and releasing objects through a simple “flip of the switch” on UV and blue LEDs. Moreover, detailed optical and thermomechanical characterization outlined the modular scope of the present platform and provided insight into the governing mechanism(s) for photoswitchable adhesion, which will serve to inform further optimization. Such stimuli responsive materials have the potential to advance applications in electronics and soft robotics that can benefit from programmable and dynamic adhesion.
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- Award ID(s):
- 2110526
- PAR ID:
- 10521709
- Publisher / Repository:
- ACS publications
- Date Published:
- Journal Name:
- Chemistry of Materials
- ISSN:
- 0897-4756
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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