The development of smart wearable electronic devices puts forward higher requirements for future flexible electronics. The design of highly sensitive and high-performance flexible pressure sensors plays an important role in promoting the development of flexible electronic devices. Recently, MXenes with excellent properties have shown great potential in the field of flexible electronics. However, the easy-stacking inclination of nanomaterials limits the development of their excellent properties and the performance improvement of related pressure sensors. Traditional methods for constructing 3D porous structures have the disadvantages of complexity, long period, and difficulty of scalability. Here, the gas foaming strategy is adopted to rapidly construct 3D porous MXene aerogels. Combining the excellent surface properties of MXenes with the porous structure of aerogel, the prepared MXene aerogels are successfully used in high-performance multifunctional flexible pressure sensors with high sensitivity (306 kPa-1), wide detection range (2.3 Pa to 87.3 kPa), fast response time (35 ms), and ultrastability (>20,000 cycles), as well as self-healing, waterproof, cold-resistant, and heat-resistant capabilities. MXene aerogel pressure sensors show great potential in harsh environment detection, behavior monitoring, equipment recovery, pressure array identification, remote monitoring, and human-computer interaction applications.
Among the increasingly popular miniature and flexible
smart electronics,
two-dimensional materials show great potential in the development
of flexible electronics owing to their layered structures and outstanding
electrical properties. MXenes have attracted much attention in flexible
electronics owing to their excellent hydrophilicity and metallic conductivity.
However, their limited interlayer spacing and tendency for self-stacking
lead to limited changes in electron channels under external pressure,
making it difficult to exploit their excellent surface metal conductivity.
We propose a strategy for rapid gas foaming to construct interlayer
tunable MXene aerogels. MXene aerogels with rich interlayer network
structures generate maximized electron channels under pressure, facilitating
the effective utilization of the surface metal properties of MXene;
this forms a self-healable flexible pressure sensor with excellent
sensing properties such as high sensitivity (1,799.5 kPa–1), fast response time (11 ms), and good cycling stability (>25,000
cycles). This pressure sensor has applications in human body detection,
human–computer interaction, self-healing, remote monitoring,
and pressure distribution identification. The maximized electron channel
design provides a simple, efficient, and scalable method to effectively
exploit the excellent surface metal conduction of 2D materials.
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