April 28, 2022
Chinese scientists develop highly robust stretchable electrode for E-skin applications
Prof. Li Runwei's group at the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences, cooperating with Prof. Zhu Guang's group from University of Nottingham Ningbo China, has developed a nano-liquid-metal-based highly robust stretchable electrode (NHSE) for multiple electronic skin (e-skin) applications, such as human healthcare monitoring and human-machine interaction. The results were published in InfoMat as a cover article.
Wearable electronics have drawn tremendous attention among consumers for realizing human-machine interface, smart medicine, and artificial intelligence. Stretchable electrodes are of paramount significance for the development of wearable electronics, especially in the stable collection of human electrophysiological signals. However, it remains challenging to prepare electrodes with superior conductivity, stretchability and durability, which plays a vital role in realizing precise and stable physiological signal collection in complex environments.
In this study, the researchers observed that a continuous and deformable water membrane can be formed when a fishing net is pulled out of the sea. Inspired by the fishing net, NHSE was developed via the in-situ assembly of electrospun elastic nanofiber scaffolds and electrosprayed liquid metal (LM) nanoparticles.
Mimicking the water-to-net interface, the self-adaptable interface between the LM and the nanofiber scaffolds contributed to a super-low resistance under high elongation.
In addition, the electrical resistance of NHSE is insensitive to a large degree of mechanical stretching, and remains stable despite cyclic deformation with only a 5% electrical resistance increase after 330,000 stretching cycles under 100% elongation.
Moreover, the NHSE delivers superior robustness under various dynamic conditions, like heating, acid and alkali exposure, as well as submersing.
Thanks to the combination of conductivity, stretchability and durability, the developed NHSE shows great potential in the application of flexible/stretchable electronics, such as wearable devices for long-term electrocardiography monitoring, electrothermal heaters, and wearable human–machine interface systems, thus facilitating the development of Internet of Things-based wearable healthcare monitoring systems and skin-like human–machine interfaces.