Nature Communications (Jun 2024)

Ag–thiolate interactions to enable an ultrasensitive and stretchable MXene strain sensor with high temporospatial resolution

  • Yang Liu,
  • Zijun Xu,
  • Xinyi Ji,
  • Xin Xu,
  • Fei Chen,
  • Xiaosen Pan,
  • Zhiqiang Fu,
  • Yunzhi Chen,
  • Zhengjian Zhang,
  • Hongbin Liu,
  • Bowen Cheng,
  • Jiajie Liang

DOI
https://doi.org/10.1038/s41467-024-49787-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 10

Abstract

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Abstract High-sensitivity strain sensing elements with a wide strain range, fast response, high stability, and small sensing areas are desirable for constructing strain sensor arrays with high temporospatial resolution. However, current strain sensors rely on crack-based conductive materials having an inherent tradeoff between their sensing area and performance. Here, we present a molecular-level crack modulation strategy in which we use layer-by-layer assembly to introduce strong, dynamic, and reversible coordination bonds in an MXene and silver nanowire-matrixed conductive film. We use this approach to fabricate a crack-based stretchable strain sensor with a very small sensing area (0.25 mm2). It also exhibits an ultrawide working strain range (0.001–37%), high sensitivity (gauge factor ~500 at 0.001% and >150,000 at 35%), fast response time, low hysteresis, and excellent long-term stability. Based on this high-performance sensing element and facile assembly process, a stretchable strain sensor array with a device density of 100 sensors per cm2 is realized. We demonstrate the practical use of the high-density strain sensor array as a multichannel pulse sensing system for monitoring pulses in terms of their spatiotemporal resolution.