摘要
Electronic skin(e-skin),a new generation of flexible electronics,has drawn interest in soft robotics,artificial intelligence,and biomedical devices.However,most existing e-skins involve complex preparation procedures and are characterized by singlesensing capability and insufficient scalability.Here,we report on a one-step strategy in which a thermionic source is used for the in situ molecularization of bacterial cellulose polymeric fibers into molecular chains,controllably constructing an ionogel with a scalable mode for e-skin.The synergistic effect of a molecular-scale hydrogen bond interweaving network and a nanoscale fiber skeleton confers a robust tensile strength(up to 7.8 MPa)and high ionic conductivity(up to 62.58 mS/cm)on the as-developed ionogel.Inspired by the tongue to engineer the perceptual patterns in this ionogel,we present a smart e-skin with the perfect combination of excellent ion transport and discriminability,showing six stimulating responses to pressure,touch,temperature,humidity,magnetic force,and even astringency.This study proposes a simple,efficient,controllable,and sustainable approach toward a low-carbon,versatile,and scalable e-skin design and structure-performance development.
出处
《Research》
EI
CAS
CSCD
2022年第4期249-259,共11页
研究(英文)
基金
This work was supported by the National Natural Science Foundation of China(Grants No.32171720)
the China National Science Fund for Distinguished Young Scholars(Grants No.31925028)
the Natural Science Foundation of Liaoning Province(Grants No.2020-BS-171)
P.R.China,and the Foundation(No.202101)of Tianjin Key Laboratory of Pulp&Paper(Tianjin University of Science&Technology),P.R.China.
