TY - JOUR
T1 - Stretchable and Self-Healable Fiber-Shaped Conductors Suitable for Harsh Environments
AU - Rong, Mingming
AU - Chen, Dongdong
AU - Hu, Hong
AU - Chen, Fan
AU - Zhang, Yaokang
AU - Xie, Chuan
AU - Chen, Zijian
AU - Yu, You
AU - Xie, Yujie
AU - Yao, Haimin
AU - Huang, Qiyao
AU - Zheng, Zijian
N1 - Funding Information:
The authors acknowledge the Guangdong‐Hong Kong Technology Cooperation Funding Scheme (Grant No. GHP/084/18SZ), the RGC Senior Research Fellow Scheme (Grant No. SRFS2122‐5S04), the Shenzhen Science and Technology Innovation Committee (Grant No. SGDX20210823103403033), and Projects of PolyU RI‐Wear (Grant No. 1‐CD8D) for financial support of this work. The authors also thank University Research Facility in Materials Characterization and Device Fabrication for characterization support.
Publisher Copyright:
© 2023 Wiley-VCH GmbH.
PY - 2023
Y1 - 2023
N2 - Fiber-shaped conductors with high electrical conductivity, stretchability, and durability have attracted increasing attention due to their potential for integration into arbitrary wearable forms. However, these fiber conductors still suffer from low reliability and short life span, particularly in harsh environments. Herein, a conductive, environment-tolerant, stretchable, and healable fiber conductor (CESH), which consists of a self-healable and stretchable organohydrogel fiber core, a conductive and buckled silver nanowire coating, and a self-healable and waterproof protective sheath, is reported. Such a multilayer core–sheath design not only offers high stretchability (≈2400%), high electrical conductivity (1.0 × 106 S m−1), outstanding self-healing ability and durability, but also possesses unprecedented tolerance in harsh environments including wide working temperature (−60–20 °C), arid (≈10 % RH (RH: room humidity)), and underwater conditions. As proof-of-concept demonstrations, CESHs are integrated into various wearable formats as interconnectors to steadily perform the electric function under different mechanical deformations and harsh conditions. Such a new type of multifunctional fiber conductors can bridge the gap in stretchable and self-healing fiber technologies by providing ultrastable electrical conductance and excellent environmental tolerance, which can greatly expand the range of applications for fiber conductors.
AB - Fiber-shaped conductors with high electrical conductivity, stretchability, and durability have attracted increasing attention due to their potential for integration into arbitrary wearable forms. However, these fiber conductors still suffer from low reliability and short life span, particularly in harsh environments. Herein, a conductive, environment-tolerant, stretchable, and healable fiber conductor (CESH), which consists of a self-healable and stretchable organohydrogel fiber core, a conductive and buckled silver nanowire coating, and a self-healable and waterproof protective sheath, is reported. Such a multilayer core–sheath design not only offers high stretchability (≈2400%), high electrical conductivity (1.0 × 106 S m−1), outstanding self-healing ability and durability, but also possesses unprecedented tolerance in harsh environments including wide working temperature (−60–20 °C), arid (≈10 % RH (RH: room humidity)), and underwater conditions. As proof-of-concept demonstrations, CESHs are integrated into various wearable formats as interconnectors to steadily perform the electric function under different mechanical deformations and harsh conditions. Such a new type of multifunctional fiber conductors can bridge the gap in stretchable and self-healing fiber technologies by providing ultrastable electrical conductance and excellent environmental tolerance, which can greatly expand the range of applications for fiber conductors.
KW - conductive
KW - environmental tolerance
KW - fiber-shaped conductors
KW - sandwiched structures
KW - self-healing
KW - stretchable
UR - http://www.scopus.com/inward/record.url?scp=85168598191&partnerID=8YFLogxK
U2 - 10.1002/smll.202304353
DO - 10.1002/smll.202304353
M3 - Journal article
AN - SCOPUS:85168598191
SN - 1613-6810
JO - Small
JF - Small
ER -