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Stretchable piezoelectric biocrystal thin films

Author

Listed:
  • Jun Li

    (University of Wisconsin-Madison)

  • Corey Carlos

    (University of Wisconsin-Madison)

  • Hao Zhou

    (Zhengzhou University)

  • Jiajie Sui

    (University of Wisconsin-Madison)

  • Yikai Wang

    (University of Wisconsin-Madison)

  • Zulmari Silva-Pedraza

    (University of Wisconsin-Madison
    University of Wisconsin-Madison)

  • Fan Yang

    (Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai)

  • Yutao Dong

    (University of Wisconsin-Madison)

  • Ziyi Zhang

    (University of Wisconsin-Madison)

  • Timothy A. Hacker

    (University of Wisconsin–Madison)

  • Bo Liu

    (University of Wisconsin-Madison)

  • Yanchao Mao

    (Zhengzhou University)

  • Xudong Wang

    (University of Wisconsin-Madison)

Abstract

Stretchability is an essential property for wearable devices to match varying strains when interfacing with soft tissues or organs. While piezoelectricity has broad application potentials as tactile sensors, artificial skins, or nanogenerators, enabling tissue-comparable stretchability is a main roadblock due to the intrinsic rigidity and hardness of the crystalline phase. Here, an amino acid-based piezoelectric biocrystal thin film that offers tissue-compatible omnidirectional stretchability with unimpaired piezoelectricity is reported. The stretchability was enabled by a truss-like microstructure that was self-assembled under controlled molecule-solvent interaction and interface tension. Through the open and close of truss meshes, this large scale biocrystal microstructure was able to endure up to 40% tensile strain along different directions while retained both structural integrity and piezoelectric performance. Built on this structure, a tissue-compatible stretchable piezoelectric nanogenerator was developed, which could conform to various tissue surfaces, and exhibited stable functions under multidimensional large strains. In this work, we presented a promising solution that integrates piezoelectricity, stretchability and biocompatibility in one material system, a critical step toward tissue-compatible biomedical devices.

Suggested Citation

  • Jun Li & Corey Carlos & Hao Zhou & Jiajie Sui & Yikai Wang & Zulmari Silva-Pedraza & Fan Yang & Yutao Dong & Ziyi Zhang & Timothy A. Hacker & Bo Liu & Yanchao Mao & Xudong Wang, 2023. "Stretchable piezoelectric biocrystal thin films," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-42184-8
    DOI: 10.1038/s41467-023-42184-8
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    References listed on IDEAS

    as
    1. Takao Someya & Zhenan Bao & George G. Malliaras, 2016. "The rise of plastic bioelectronics," Nature, Nature, vol. 540(7633), pages 379-385, December.
    2. Laiming Jiang & Gengxi Lu & Yushun Zeng & Yizhe Sun & Haochen Kang & James Burford & Chen Gong & Mark S. Humayun & Yong Chen & Qifa Zhou, 2022. "Flexible ultrasound-induced retinal stimulating piezo-arrays for biomimetic visual prostheses," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
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