TY - JOUR
T1 - The weaving art of mechanically and electronically robust hydrogel realizes multi-dimensional response of stretchable sensors
AU - Zhou, Yang
AU - Mi, Yuanyuan
AU - Liu, Yinping
AU - Luo, Xiaohang
AU - Chen, Neng
AU - Wang, Lulu
AU - Guo, Chao
AU - Lv, Wenjie
AU - Peng, Bo
AU - Niu, Yingchun
AU - Xu, Quan
N1 - Funding Information:
We acknowledge funding support from the Science Foundation of National Natural Science Foundation of China (No. 52211530034 ), Beijing National Science Foundation (No. 3222018 ), and China University of Petroleum, Beijing (No. 2462019BJRC007 , 2462020YXZZ018 ).
Publisher Copyright:
© 2023 Elsevier Ltd
PY - 2023/10
Y1 - 2023/10
N2 - In recent years, hydrogel-based soft electronics have been developed for the application of human motion, flexible robots and foldable displays. However, most existing conductive hydrogels have low toughness, single electron conduction or ionic conduction and poor adaptability towards complex applications. In this work, we obtained the toughness fiber-like hydrogel in three steps by doping nanofillers, directional extrusion freezing, and salting out. The proposed tough fiber-like hydrogel has a rich porous structure, which is achieved by doping the hydrophilic graphene nanosheets (HGNs) into a physically cross-linking polyvinyl alcohol (PVA) gel matrix. Directional extrusion freezing and salting out effect endow fiber-like hydrogel with better orientation ultimate nominal stress (∼9.5 MPa) and nominal strain (∼2200%). Meanwhile, the abundant porous structure facilitates ion migration and greatly enhances the ionic conductivity (up to 2.8 S m −1, at f = 1 MHz) of the hydrogel. The presence of HGNs endows the fiber-like hydrogel with excellent electronic conduction properties. Moreover, the weaving strategy is proposed to fabricate fiber-like hydrogel into hydrogel fabric film, which is effective for increased safety of stress-induced deformation and crack propagation. The woven hydrogel mesh bag can lift 6 kg of watermelon and the woven hydrogel net can bear a top-down weight impact of 1 kg. We also develop a novel type of woven hydrogel glove that can monitor complex hand movement. This work will provide new insight into the design of multifunctional materials with applications on electronic skin, wearable devices, and health monitoring.
AB - In recent years, hydrogel-based soft electronics have been developed for the application of human motion, flexible robots and foldable displays. However, most existing conductive hydrogels have low toughness, single electron conduction or ionic conduction and poor adaptability towards complex applications. In this work, we obtained the toughness fiber-like hydrogel in three steps by doping nanofillers, directional extrusion freezing, and salting out. The proposed tough fiber-like hydrogel has a rich porous structure, which is achieved by doping the hydrophilic graphene nanosheets (HGNs) into a physically cross-linking polyvinyl alcohol (PVA) gel matrix. Directional extrusion freezing and salting out effect endow fiber-like hydrogel with better orientation ultimate nominal stress (∼9.5 MPa) and nominal strain (∼2200%). Meanwhile, the abundant porous structure facilitates ion migration and greatly enhances the ionic conductivity (up to 2.8 S m −1, at f = 1 MHz) of the hydrogel. The presence of HGNs endows the fiber-like hydrogel with excellent electronic conduction properties. Moreover, the weaving strategy is proposed to fabricate fiber-like hydrogel into hydrogel fabric film, which is effective for increased safety of stress-induced deformation and crack propagation. The woven hydrogel mesh bag can lift 6 kg of watermelon and the woven hydrogel net can bear a top-down weight impact of 1 kg. We also develop a novel type of woven hydrogel glove that can monitor complex hand movement. This work will provide new insight into the design of multifunctional materials with applications on electronic skin, wearable devices, and health monitoring.
KW - Fiber-like graphene hydrogel
KW - Multi-dimensional response
KW - Robust hydrogel
KW - Stretchable sensor
KW - Woven
UR - http://www.scopus.com/inward/record.url?scp=85167781485&partnerID=8YFLogxK
U2 - 10.1016/j.apmt.2023.101894
DO - 10.1016/j.apmt.2023.101894
M3 - Article
AN - SCOPUS:85167781485
SN - 2352-9407
VL - 34
JO - Applied Materials Today
JF - Applied Materials Today
M1 - 101894
ER -