posted on 2022-02-28, 18:35authored byRamadan Borayek, Firoozeh Foroughi, Xu Xin, Ayman Mahmoud Mohamed, Mahmoud M. Abdelrahman, Mostafa Zedan, Danwei Zhang, Jun Ding
Soft
conductive elastomers with low hysteresis over a wide range
of stretchability are desirable in various applications. Such applications
include soft sensors with a long measurement range, motion recognition,
and electronic skin, just to name a few. Even though the measurement
capability of the sensors based on soft materials has been greatly
improved compared to the traditional ones in recent years, hysteresis
in the loading and unloading states has limited the applications of
these sensors, thereby negatively affecting their accuracy and reliability.
In this work, conductive elastomers with near-zero hysteresis have
been formulated and fabricated using 3D printing. These elastomers
are made by combining highly stretchable dielectric elastomer formulations
with a polar hydrophobic ionic liquid and polymerizing under ultraviolet
light. High-performance piezoresistive sensors have been fabricated
and characterized, with a 10-fold stretchability and low hysteresis
(1.2%) over long-term stability (more than 10 000 cycles under
cyclic stress) with a 20 ms response time. Additionally, the current
elastomers displayed fast mechanical and electrical self-healing properties.
Using 3D printing in conjunction with some of our structural innovations,
we have fabricated smart gloves to show this material’s wide
range of applications in soft robots, motion detection, wearable devices,
and medical care.