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High-Performance Flexible Piezoresistive Sensor Based on Ti3C2Tx MXene with a Honeycomb-like Structure for Human Activity Monitoring

2022-07-12

 

Author(s): Su, Y (Su, Yue); Ma, KN (Ma, Kainan); Yuan, F (Yuan, Fang); Tang, J (Tang, Jun); Liu, M (Liu, Ming); Zhang, X (Zhang, Xu)

Source: MICROMACHINES Volume: 13 Issue: 6 Article Number: 821 DOI: 10.3390/mi13060821 Published: JUN 2022

Abstract: Wearable and flexible pressure sensors have sparked great interest due to their unique capacity to conformally attach to the surface of the skin and quantify human activities into recordable electric signals. As a result, more and more research efforts are being devoted to developing high-sensitivity and cost-effective flexible sensors for monitoring an individual's state of activity. Herein, a high-performance flexible piezoresistive sensor was designed and fabricated by combing 2D transition metal carbides, nitrides, and carbonitrides (MXene) with a honeycomb-like structure formed by femtosecond filamentating pulses. The sensing mechanism is attributed to the change of the connecting conductive paths between the top interdigital electrodes and the bottom microstructured films coated with MXene. The obtained sensing device demonstrates high sensitivity of 0.61 kPa(-1), relatively short response time, and excellent reliability and stability. Benefiting from the aforementioned extraordinary sensing performance, the sensor can be used with success to monitor tiny physiological signals, detect large deformations during human movement, and distinguish finger gestures, thus demonstrating its broad prospects in physiological analysis systems, health monitoring systems, and human-machine interaction.

Accession Number: WOS:000817362700001

PubMed ID: 35744435

Author Identifiers:

Author        Web of Science ResearcherID        ORCID Number

Ma, Kainan                  0000-0002-1379-591X

eISSN: 2072-666X

Full Text: https://www.mdpi.com/2072-666X/13/6/821



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