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MXene‐Induced Flexible, Water‐Retention, Semi‐Interpenetrating Network Hydrogel for Ultra‐Stable Strain Sensors with Real‐Time Gesture Recognition

Lianjia Zhao, Hao Xu, Lingchen Liu, Yiqiang Zheng, Wei Han, Lili Wang

2023Advanced Science162 citationsDOIOpen Access PDF

Abstract

As water-saturated polymer networks, hydrogels are a growing family of soft materials that have recently become promising candidates for flexible electronics application. However, it remains still difficult for hydrogel-based strain sensors to achieve the organic unity of mechanical properties, electrical conductivity, and water retention. To address this challenge, based on the template, the excellent properties of MXene nanoflakes (rich surface functional groups, high specific surface area, hydrophilicity, and conductivity) are fully utilized in this study to prepare the P(AA-co-AM)/MXene@PDADMAC semi-interpenetrating network (semi-IPN) hydrogel. The proposed hydrogel continues to exhibit excellent strain response and flexibility after 30 days of storage at room temperature, and its performance do not decrease after 1100 cycles. Considering these characteristics, a hydrogel-based device for converting sign language into Chinese characters is successfully developed and optimized using machine learning. Therefore, this study provides novel insight and application directions for hydrogel families.

Topics & Concepts

Materials scienceSelf-healing hydrogelsFlexibility (engineering)ConductivityNanotechnologyPolymerComposite materialElectronicsChemical engineeringPolymer chemistryChemistryPhysical chemistryMathematicsEngineeringStatisticsAdvanced Sensor and Energy Harvesting MaterialsMXene and MAX Phase MaterialsConducting polymers and applications
MXene‐Induced Flexible, Water‐Retention, Semi‐Interpenetrating Network Hydrogel for Ultra‐Stable Strain Sensors with Real‐Time Gesture Recognition | Litcius