Conductive hydrogels as flexible electronic devices, not only have unique attractions but also meet the basic need of mechanical flexibility and intelligent sensing. How to endow anisotropy and a wide application temperature range for traditional homogeneous conductive hydrogels and flexible sensors is still a challenge. Herein, a directional freezing method is used to prepare anisotropic MXene conductive hydrogels that are inspired by ordered structures of muscles. Due to the anisotropy of MXene conductive hydrogels, the mechanical properties and electrical conductivity are enhanced in specific directions. The hydrogels have a wide temperature resistance range of −36 to 25 °C through solvent substitution. Thus, the muscle-inspired MXene conductive hydrogels with anisotropy and low-temperature resistance can be used as wearable flexible sensors. The sensing signals are further displayed on the mobile phone as images through wireless technology, and images will change with the collected signals to achieve motion detection. Multiple flexible sensors are also assembled into a 3D sensor array for detecting the magnitude and spatial distribution of forces or strains. The MXene conductive hydrogels with ordered orientation and anisotropy are promising for flexible sensors, which have broad application prospects in human-machine interface compatibility and medical monitoring.
Conductive hydrogels
had demonstrated significant prospect in the
field of wearable devices. However, hydrogels suffer from a huge limitation of freezing when the temperature
falls below zero. Here, a novel conductive organohydrogel was developed
by introducing polyelectrolytes and glycerol into hydrogels. The gel
exhibited excellent elongation, self-healing, and self-adhesive performance
for various materials. Moreover, the gel could withstand a low temperature
of −20 °C for 24 h without freezing and still maintain
good conductivity and self-healing properties. As a result, the sample
could be applied for motion detection and signal transmission. For
example, it can respond to finger movements and transmit network signals
like network cables. Therefore, it was envisioned that the effective
design strategy for conductive organohydrogels with antifreezing,
toughness, self-healing, and self-adhesive properties would provide
wide applications of flexible wearable devices.
Traditional optoelectronic devices without stretchable performance could be limited for substrates with irregular shape. Therefore, it is urgent to explore a new generation of flexible, stretchable, and low-cost intelligent vehicles as visual display and storage devices, such as hydrogels. In the investigation, a novel photochromic hydrogel was developed by introducing the negatively charged ammonium molybdate as a photochromic unit into polyacrylamide via ionic and covalent cross-linking. The hydrogel exhibited excellent properties of low cost, easy preparation, stretchable deformation, fatigue resistance, high transparency, and second-order response to external signals. Moreover, the photochromic and fading process of hydrogels could be precisely controlled and repeated under the irradiation of UV light and exposure of oxygen at different time and temperature. The photochromic hydrogel could be considered applied for artificial intelligence system, wearable healthcare device, and flexible memory device. Therefore, the strategy for designing a soft photochromic material would open a new direction to manufacture flexible and stretchable devices.
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