Litcius/Paper detail

Microporous MXene/Polyurethane Gels Derived from Iron Foam Templates for Ultra-High Stable Pressure Sensors and Triboelectric Nanogenerators

Senjing Wang, Zhuomin Chen, Hao Zhou, Xiaoguang Fu, Bingqi Chen, Fangqiao Wang, Andeng Liu, Wenxi Guo, Meidan Ye

2024ACS Applied Electronic Materials16 citationsDOI

Abstract

Designing high-performance conductive polymer composites with three-dimensional (3D) porous structures for pressure sensors is still challenging, limiting their applications in various settings. Herein, a facile route for fabricating 3D microporous MXene/polyurethane (MXene/PU) composite gels is developed via a template strategy. The iron foam acts as a template to provide a framework for the 3D network structure, while PU and MXene form a robust organic/inorganic network through inter- and intramolecular hydrogen bonding interactions. The resulting MXene/PU composite gel, when configured into a piezoresistive sensor, exhibits exceptional performance characteristics with a large compressive range (2.6 MPa, 60% deformation), excellent cycling durability (over 12000 cycles within 1 day), long-term stability (maintaining functionality over 20 days with 20000 cycles), and high sensitivity (0.96144 kPa –1 ). Furthermore, the MXene/PU sensor demonstrates remarkable effectiveness in plantar health monitoring, showcasing its potential for applications in human health care and rehabilitation. Additionally, the applicability of MXene/PU gels in triboelectric nanogenerators has been explored, expanding the scope of their potential applications. Our findings highlight the versatility and promise of MXene/PU gels in the field of advanced wearable electronic sensors.

Topics & Concepts

Materials scienceTriboelectric effectMicroporous materialMXenesComposite numberPolyurethaneNanotechnologyNanoporousPiezoresistive effectPolymerPorosityComposite materialAdvanced Sensor and Energy Harvesting MaterialsMXene and MAX Phase MaterialsConducting polymers and applications