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Reversible polymer-gel transition for ultra-stretchable chip-integrated circuits through self-soldering and self-coating and self-healing

Author

Listed:
  • Pedro Alhais Lopes

    (Department of Electrical Engineering, University of Coimbra)

  • Bruno C. Santos

    (Department of Electrical Engineering, University of Coimbra)

  • Anibal T. Almeida

    (Department of Electrical Engineering, University of Coimbra)

  • Mahmoud Tavakoli

    (Department of Electrical Engineering, University of Coimbra)

Abstract

Integration of solid-state microchips into soft-matter, and stretchable printed electronics has been the biggest challenge against their scalable fabrication. We introduce, Pol-Gel, a simple technique for self-soldering, self-encapsulation, and self-healing, that allows low cost, scalable, and rapid fabrication of hybrid microchip-integrated ultra-stretchable circuits. After digitally printing the circuit, and placing the microchips, we trigger a Polymer-Gel transition in physically cross-linked block copolymers substrate, and silver liquid metal composite ink, by exposing the circuits to the solvent vapor. Once in the gel state, microchips penetrate to the ink and the substrate (Self-Soldering), and the ink penetrates to the substrate (Self-encapsulation). Maximum strain tolerance of ~1200% for printed stretchable traces, and >500% for chip-integrated soft circuits is achieved, which is 5x higher than the previous works. We demonstrate condensed soft-matter patches and e-textiles with integrated sensors, processors, and wireless communication, and repairing of a fully cut circuits through Pol-Gel.

Suggested Citation

  • Pedro Alhais Lopes & Bruno C. Santos & Anibal T. Almeida & Mahmoud Tavakoli, 2021. "Reversible polymer-gel transition for ultra-stretchable chip-integrated circuits through self-soldering and self-coating and self-healing," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-25008-5
    DOI: 10.1038/s41467-021-25008-5
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    Cited by:

    1. Gun-Hee Lee & Do Hoon Lee & Woojin Jeon & Jihwan Yoon & Kwangguk Ahn & Kum Seok Nam & Min Kim & Jun Kyu Kim & Yong Hoe Koo & Jinmyoung Joo & WooChul Jung & Jaehong Lee & Jaewook Nam & Seongjun Park & , 2023. "Conductance stable and mechanically durable bi-layer EGaIn composite-coated stretchable fiber for 1D bioelectronics," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    2. Liqing Ai & Weikang Lin & Chunyan Cao & Pengyu Li & Xuejiao Wang & Dong Lv & Xin Li & Zhengbao Yang & Xi Yao, 2023. "Tough soldering for stretchable electronics by small-molecule modulated interfacial assemblies," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    3. Yuzhou Shao & Lusong Wei & Xinyue Wu & Chengmei Jiang & Yao Yao & Bo Peng & Han Chen & Jiangtao Huangfu & Yibin Ying & Chuanfang John Zhang & Jianfeng Ping, 2022. "Room-temperature high-precision printing of flexible wireless electronics based on MXene inks," Nature Communications, Nature, vol. 13(1), pages 1-8, December.

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