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Large-area display textiles integrated with functional systems

Author

Listed:
  • Xiang Shi

    (Fudan University
    Fudan University
    Fudan University)

  • Yong Zuo

    (Fudan University
    Fudan University
    Fudan University)

  • Peng Zhai

    (Fudan University)

  • Jiahao Shen

    (Fudan University)

  • Yangyiwei Yang

    (Institute of Materials Science, Technische Universität Darmstadt)

  • Zhen Gao

    (Fudan University
    Fudan University
    Fudan University)

  • Meng Liao

    (Fudan University
    Fudan University
    Fudan University)

  • Jingxia Wu

    (Fudan University
    Fudan University
    Fudan University)

  • Jiawei Wang

    (Fudan University
    Fudan University
    Fudan University)

  • Xiaojie Xu

    (Fudan University
    Fudan University
    Fudan University)

  • Qi Tong

    (Fudan University)

  • Bo Zhang

    (Fudan University
    Fudan University
    Fudan University)

  • Bingjie Wang

    (Fudan University
    Fudan University
    Fudan University)

  • Xuemei Sun

    (Fudan University
    Fudan University
    Fudan University)

  • Lihua Zhang

    (Fudan University
    Ji Hua Laboratory)

  • Qibing Pei

    (University of California, Los Angeles)

  • Dayong Jin

    (University of Technology Sydney
    Southern University of Science and Technology)

  • Peining Chen

    (Fudan University
    Fudan University
    Fudan University)

  • Huisheng Peng

    (Fudan University
    Fudan University
    Fudan University)

Abstract

Displays are basic building blocks of modern electronics1,2. Integrating displays into textiles offers exciting opportunities for smart electronic textiles—the ultimate goal of wearable technology, poised to change the way in which we interact with electronic devices3–6. Display textiles serve to bridge human–machine interactions7–9, offering, for instance, a real-time communication tool for individuals with voice or speech difficulties. Electronic textiles capable of communicating10, sensing11,12 and supplying electricity13,14 have been reported previously. However, textiles with functional, large-area displays have not yet been achieved, because it is challenging to obtain small illuminating units that are both durable and easy to assemble over a wide area. Here we report a 6-metre-long, 25-centimetre-wide display textile containing 5 × 105 electroluminescent units spaced approximately 800 micrometres apart. Weaving conductive weft and luminescent warp fibres forms micrometre-scale electroluminescent units at the weft–warp contact points. The brightness between electroluminescent units deviates by less than 8 per cent and remains stable even when the textile is bent, stretched or pressed. Our display textile is flexible and breathable and withstands repeated machine-washing, making it suitable for practical applications. We show that an integrated textile system consisting of display, keyboard and power supply can serve as a communication tool, demonstrating the system’s potential within the ‘internet of things’ in various areas, including healthcare. Our approach unifies the fabrication and function of electronic devices with textiles, and we expect that woven-fibre materials will shape the next generation of electronics.

Suggested Citation

  • Xiang Shi & Yong Zuo & Peng Zhai & Jiahao Shen & Yangyiwei Yang & Zhen Gao & Meng Liao & Jingxia Wu & Jiawei Wang & Xiaojie Xu & Qi Tong & Bo Zhang & Bingjie Wang & Xuemei Sun & Lihua Zhang & Qibing P, 2021. "Large-area display textiles integrated with functional systems," Nature, Nature, vol. 591(7849), pages 240-245, March.
  • Handle: RePEc:nat:nature:v:591:y:2021:i:7849:d:10.1038_s41586-021-03295-8
    DOI: 10.1038/s41586-021-03295-8
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    Citations

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    Cited by:

    1. Tian Tian & Meifang Yang & Yuxuan Fang & Shuo Zhang & Yuxin Chen & Lianzhou Wang & Wu-Qiang Wu, 2023. "Large-area waterproof and durable perovskite luminescent textiles," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    2. Songlin Zhang & Mengjuan Zhou & Mingyang Liu & Zi Hao Guo & Hao Qu & Wenshuai Chen & Swee Ching Tan, 2023. "Ambient-conditions spinning of functional soft fibers via engineering molecular chain networks and phase separation," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    3. Nan Gan & Xin Zou & Zhao Qian & Anqi Lv & Lan Wang & Huili Ma & Hu-Jun Qian & Long Gu & Zhongfu An & Wei Huang, 2024. "Stretchable phosphorescent polymers by multiphase engineering," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    4. Tianzhu Zhou & Yangzhe Yu & Bing He & Zhe Wang & Ting Xiong & Zhixun Wang & Yanting Liu & Jiwu Xin & Miao Qi & Haozhe Zhang & Xuhui Zhou & Liheng Gao & Qunfeng Cheng & Lei Wei, 2022. "Ultra-compact MXene fibers by continuous and controllable synergy of interfacial interactions and thermal drawing-induced stresses," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
    5. Hyung Woo Choi & Dong-Wook Shin & Jiajie Yang & Sanghyo Lee & Cátia Figueiredo & Stefano Sinopoli & Kay Ullrich & Petar Jovančić & Alessio Marrani & Roberto Momentè & João Gomes & Rita Branquinho & Um, 2022. "Smart textile lighting/display system with multifunctional fibre devices for large scale smart home and IoT applications," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    6. Chuanqian Shi & Jing Jiang & Chenglong Li & Chenhong Chen & Wei Jian & Jizhou Song, 2024. "Precision-induced localized molten liquid metal stamps for damage-free transfer printing of ultrathin membranes and 3D objects," Nature Communications, Nature, vol. 15(1), pages 1-14, December.
    7. Pengwei Wang & Xiaohao Ma & Zhiqiang Lin & Fan Chen & Zijian Chen & Hong Hu & Hailong Xu & Xinyi Zhang & Yuqing Shi & Qiyao Huang & Yuanjing Lin & Zijian Zheng, 2024. "Well-defined in-textile photolithography towards permeable textile electronics," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    8. Ying Liu & Chan Wang & Zhuo Liu & Xuecheng Qu & Yansong Gai & Jiangtao Xue & Shengyu Chao & Jing Huang & Yuxiang Wu & Yusheng Li & Dan Luo & Zhou Li, 2024. "Self-encapsulated ionic fibers based on stress-induced adaptive phase transition for non-contact depth-of-field camouflage sensing," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    9. Rongzhou Lin & Han-Joon Kim & Sippanat Achavananthadith & Ze Xiong & Jason K. W. Lee & Yong Lin Kong & John S. Ho, 2022. "Digitally-embroidered liquid metal electronic textiles for wearable wireless systems," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    10. Dongxu Ma & Ming Ji & Hongbo Yi & Qingyu Wang & Fu Fan & Bo Feng & Mengjie Zheng & Yiqin Chen & Huigao Duan, 2024. "Pushing the thinness limit of silver films for flexible optoelectronic devices via ion-beam thinning-back process," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    11. Hong Xiang & Yongfu Li & Qinglong Liao & Lei Xia & Xiaodong Wu & Huang Zhou & Chunmei Li & Xing Fan, 2024. "Recent Advances in Smart Fabric-Type Wearable Electronics toward Comfortable Wearing," Energies, MDPI, vol. 17(11), pages 1-36, May.
    12. Pei Zhang & Iek Man Lei & Guangda Chen & Jingsen Lin & Xingmei Chen & Jiajun Zhang & Chengcheng Cai & Xiangyu Liang & Ji Liu, 2022. "Integrated 3D printing of flexible electroluminescent devices and soft robots," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    13. Tianyu Wang & Jialin Meng & Xufeng Zhou & Yue Liu & Zhenyu He & Qi Han & Qingxuan Li & Jiajie Yu & Zhenhai Li & Yongkai Liu & Hao Zhu & Qingqing Sun & David Wei Zhang & Peining Chen & Huisheng Peng & , 2022. "Reconfigurable neuromorphic memristor network for ultralow-power smart textile electronics," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    14. Haojie Lu & Yong Zhang & Mengjia Zhu & Shuo Li & Huarun Liang & Peng Bi & Shuai Wang & Haomin Wang & Linli Gan & Xun-En Wu & Yingying Zhang, 2024. "Intelligent perceptual textiles based on ionic-conductive and strong silk fibers," Nature Communications, Nature, vol. 15(1), pages 1-9, December.

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