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Room-temperature high-precision printing of flexible wireless electronics based on MXene inks

Engineering and Technology

Room-temperature high-precision printing of flexible wireless electronics based on MXene inks

Y. Shao, L. Wei, et al.

Discover the groundbreaking advancements in wireless technologies with flexible printed electronics, as Yuzhou Shao and colleagues unveil a room-temperature direct printing strategy that creates high-performance modules like antennas and sensors. This innovative approach revolutionizes the precision of additive manufacturing for the Internet of Things and wearable applications.

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Playback language: English
Abstract
Wireless technologies-supported printed flexible electronics are crucial for the Internet of Things (IoTs), human-machine interaction, wearable and biomedical applications. However, the challenges to existing printing approaches remain, such as low printing precision, difficulty in conformal printing, complex ink formulations and processes. Here we present a room-temperature direct printing strategy for flexible wireless electronics, where distinct high-performance functional modules (e.g., antennas, micro-supercapacitors, and sensors) can be fabricated with high resolution and further integrated on various flat/curved substrates. The additive-free titanium carbide (Ti3C2Tx) MXene aqueous inks are regulated with large single-layer ratio (>90%) and narrow flake size distribution, offering metallic conductivity (-6, 900 S cm-1) in the ultrafine-printed tracks (3 µm line gap and 0.43% spatial uniformity) without annealing. In particular, we build an all-MXene-printed integrated system capable of wireless communication, energy harvesting, and smart sensing. This work opens a door for high-precision additive manufacturing of printed wireless electronics at room temperature.
Publisher
Nature Communications
Published On
Jun 09, 2022
Authors
Yuzhou Shao, Lusong Wei, Xinyue Wu, Chengmei Jiang, Yao Yao, Bo Peng, Han Chen, Jiangtao Huangfu, Yibin Ying, Chuanfang John Zhang, Jianfeng Ping
Tags
wireless technologies
printed electronics
room-temperature printing
MXene
additive manufacturing
sensors
energy harvesting

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