posted on 2019-07-17, 12:05authored byYanghui Chen, Xiong Pu, Mengmeng Liu, Shuangyang Kuang, Panpan Zhang, Qilin Hua, Zifeng Cong, Wenbin Guo, Weiguo Hu, Zhong Lin Wang
The
viable application of soft electronics/robotics relies on the
development of power devices which are desired to be flexible, deformable,
or even self-healable. We report here a shape-adaptive, self-healable
triboelectric nanogenerator (SS-TENG) for harvesting biomechanical
energies. The use of a viscoelastic polymer, normally known as Silly
Putty, as the electrification material and as the matrix of a carbon-nanotube-filled
composite (CNT-putty) electrode endows the SS-TENG the capability
of adapting to arbitrary irregular surfaces and instantaneous healing
from mechanical damage (almost completely recovered in 3 min without
extra stimuli). Furthermore, the output performances of the SS-TENG
have also been significantly improved because (i) the ideal soft contact
is achieved at the solid–solid interfaces for more effective
contact electrification and (ii) the introduced cation dopants make
the putty even more tribo-negative than polytetrafluoroethylene. The
SS-TENG can be adhered to any curvy surface, tailored, and reshaped
into arbitrary configurations and utilized as a power supply for small
electronics, suggesting promising applications in soft electronics/robotics
in the future.