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Phototunable, Reconfigurable, and Complex Shape Transformation of Fe<sup>3+</sup>-Containing Bilayer Polymer Materials

Lei Wang, Jingtao Jiang, Chenghao Dai, Huilan Zeng, Yifan Shang, Yongqi Liu, Qiyan Yin, Gengsheng Weng

Year
2022
Citations
11

Abstract

The design of materials that can mimic the complex shape-morphing phenomena in nature is important for applications in soft robotics, biomedical devices, and sensors. Yet, morphing a two-dimensional thin plate into a programmed complex three-dimensional (3D) shape is still challenging. Herein, we demonstrate a new paradigm for designing a photothermal shape-transformable Fe3+-containing polymer film (FePF) coated with a patterned inactive black-tape strip layer. The near-infrared (NIR) light-triggered dehydrative shrinkage of the FePF layer drives the bending of the inactive layer toward the FePF layer. Various reversible 3D shapes, including a complex “human face” and gripping-force-tunable soft grippers, are fabricated by the experimental pattern design of the inactive layer with the aid of theoretical simulations. The white-light sensitive dynamic coordination of Fe3+–Alanine (Ala) enables tunability of the deformation degree under white-light irradiation. The deformation rate is also tunable by adjusting the Fe-to-Ala mole ratio, humidity, NIR light intensity, and FePF thickness. These shape transformations are reconfigurable through the simple peeling off and repatterning of the black-tape strip layers. Our simple and scalable design strategy without an intricate heterogeneity design in material properties provides guidance for fabricating new soft robotics and biomimetic systems.

Keywords

Materials scienceMorphingSoft roboticsLayer (electronics)Deformation (meteorology)PolymerBilayerNanotechnologyOptoelectronicsComposite material

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