TY - JOUR
T1 - Multilayer Graphene Epidermal Electronic Skin
AU - Qiao, Yancong
AU - Wang, Yunfan
AU - Tian, He
AU - Li, Mingrui
AU - Jian, Jinming
AU - Wei, Yuhong
AU - Tian, Ye
AU - Wang, Dan Yang
AU - Pang, Yu
AU - Geng, Xiangshun
AU - Wang, Xuefeng
AU - Zhao, Yunfei
AU - Wang, Huimin
AU - Deng, Ningqin
AU - Jian, Muqiang
AU - Zhang, Yingying
AU - Liang, Renrong
AU - Yang, Yi
AU - Ren, Tian Ling
N1 - Publisher Copyright:
© 2018 American Chemical Society.
PY - 2018/9/25
Y1 - 2018/9/25
N2 - Due to its excellent flexibility, graphene has an important application prospect in epidermal electronic sensors. However, there are drawbacks in current devices, such as sensitivity, range, lamination, and artistry. In this work, we have demonstrated a multilayer graphene epidermal electronic skin based on laser scribing graphene, whose patterns are programmable. A process has been developed to remove the unreduced graphene oxide. This method makes the epidermal electronic skin not only transferable to butterflies, human bodies, and any other objects inseparably and elegantly, merely with the assistance of water, but also have better sensitivity and stability. Therefore, pattern electronic skin could attach to every object like artwork. When packed in Ecoflex, electronic skin exhibits excellent performance, including ultrahigh sensitivity (gauge factor up to 673), large strain range (as high as 10%), and long-term stability. Therefore, many subtle physiological signals can be detected based on epidermal electronic skin with a single graphene line. Electronic skin with multiple graphene lines is employed to detect large-range human motion. To provide a deeper understanding of the resistance variation mechanism, a physical model is established to explain the relationship between the crack directions and electrical characteristics. These results show that graphene epidermal electronic skin has huge potential in health care and intelligent systems.
AB - Due to its excellent flexibility, graphene has an important application prospect in epidermal electronic sensors. However, there are drawbacks in current devices, such as sensitivity, range, lamination, and artistry. In this work, we have demonstrated a multilayer graphene epidermal electronic skin based on laser scribing graphene, whose patterns are programmable. A process has been developed to remove the unreduced graphene oxide. This method makes the epidermal electronic skin not only transferable to butterflies, human bodies, and any other objects inseparably and elegantly, merely with the assistance of water, but also have better sensitivity and stability. Therefore, pattern electronic skin could attach to every object like artwork. When packed in Ecoflex, electronic skin exhibits excellent performance, including ultrahigh sensitivity (gauge factor up to 673), large strain range (as high as 10%), and long-term stability. Therefore, many subtle physiological signals can be detected based on epidermal electronic skin with a single graphene line. Electronic skin with multiple graphene lines is employed to detect large-range human motion. To provide a deeper understanding of the resistance variation mechanism, a physical model is established to explain the relationship between the crack directions and electrical characteristics. These results show that graphene epidermal electronic skin has huge potential in health care and intelligent systems.
KW - GO lift-off
KW - crack simulation
KW - epidermal skin
KW - laser scribed graphene
KW - programmable pattern
UR - https://www.scopus.com/pages/publications/85050777239
U2 - 10.1021/acsnano.8b02162
DO - 10.1021/acsnano.8b02162
M3 - 文章
C2 - 30040381
AN - SCOPUS:85050777239
SN - 1936-0851
VL - 12
SP - 8839
EP - 8846
JO - ACS Nano
JF - ACS Nano
IS - 9
ER -
