Nature Communications (Aug 2024)

Wide-range and high-accuracy wireless sensor with self-humidity compensation for real-time ammonia monitoring

  • Wen Lv,
  • Jianhua Yang,
  • Qingda Xu,
  • Jaafar Abdul-Aziz Mehrez,
  • Jia Shi,
  • Wenjing Quan,
  • Hanyu Luo,
  • Min Zeng,
  • Nantao Hu,
  • Tao Wang,
  • Hao Wei,
  • Zhi Yang

DOI
https://doi.org/10.1038/s41467-024-51279-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 13

Abstract

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Abstract Real-time and accurate biomarker detection is highly desired in point-of-care diagnosis, food freshness monitoring, and hazardous leakage warning. However, achieving such an objective with existing technologies is still challenging. Herein, we demonstrate a wireless inductor-capacitor (LC) chemical sensor based on platinum-doped partially deprotonated-polypyrrole (Pt-PPy+ and PPy0) for real-time and accurate ammonia (NH3) detection. With the chemically wide-range tunability of PPy in conductivity to modulate the impedance, the LC sensor exhibits an up-to-180% improvement in return loss (S11). The Pt-PPy+ and PPy0 shows the p-type semiconductor nature with greatly-manifested adsorption-charge transfer dynamics toward NH3, leading to an unprecedented NH3 sensing range. The S11 and frequency of the Pt-PPy+ and PPy0-based sensor exhibit discriminative response behaviors to humidity and NH3, enabling the without-external-calibration compensation and accurate NH3 detection. A portable system combining the proposed wireless chemical sensor and a handheld instrument is validated, which aids in rationalizing strategies for individuals toward various scenarios.