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Ultrafast Polymerization of a Self-Adhesive and Strain Sensitive Hydrogel-Based Flexible Sensor for Human Motion Monitoring and Handwriting Recognition

Bin Du, Mengwei Yin, Kenan Yang, Sainan Wang, Yiting Pei, Rubai Luo, Shisheng Zhou, Huailin Li

2024Polymers19 citationsDOIOpen Access PDF

Abstract

Hydrogel-based flexible electronic devices have great potential in human motion monitoring, electronic skins, and human-computer interaction applications; hence, the efficient preparation of highly sensitive hydrogel-based flexible sensors is important. In the present work, the ultrafast polymerization of a hydrogel (1–3 min) was achieved by constructing a tannic acid (TA)-Fe3+ dynamic redox system, which endowed the hydrogel with good adhesion performance (the adhesion strength in wood was 17.646 kPa). In addition, the uniform dispersal ensured by incorporating polydopamine-decorated polypyrrole (PPy@PDA) into the hydrogel matrix significantly improved the hydrogel’s stretching ability (575.082%). The as-prepared PAM/CS/PPy@PDA/TA hydrogel-based flexible sensor had a high-fidelity low detection limit (strain = 1%), high sensitivity at small strains (GF = 5.311 at strain = 0–8%), and fast response time (0.33 s) and recovery time (0.25 s), and it was reliably applied to accurate human motion monitoring and handwriting recognition. The PAM/CS/PPy@PDA/TA hydrogel opens new horizons for wearable electronic devices, electronic skins, and human-computer interaction applications.

Topics & Concepts

Materials scienceHuman motionPolypyrroleNanotechnologySelf-healing hydrogelsPolymerizationAdhesionPolymerComputer scienceComposite materialPolymer chemistryMotion (physics)Artificial intelligenceAdvanced Sensor and Energy Harvesting MaterialsConducting polymers and applicationsPolydiacetylene-based materials and applications