Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation

Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation

Stretchable conductors are the basic units of advanced flexible electronic devices, such as skin‐like sensors, stretchable batteries and soft actuators. Current fabrication strategies are mainly focused on the stretchability of the conductor with less emphasis on the huge mismatch of the conductive...

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Main Authors: Liu, Zhiyuan, Wang, Hui, Huang, Pingao, Huang, Jianping, Zhang, Yu, Wang, Yuanyuan, Yu, Mei, Chen, Shixiong, Qi, Dianpeng, Wang, Ting, Jiang, Ying, Chen, Geng, Hu, Guoyu, Li, Wenlong, Yu, Jiancan, Luo, Yifei, Loh, Xian Jun, Liedberg, Bo, Li, Guanglin, Chen, Xiaodong
Other Authors: School of Materials Science & Engineering
Format: Article
Language:English
Published: 2020
Subjects:
Engineering::Materials
Adhesion
Interlocking Effect
Online Access:https://hdl.handle.net/10356/137870
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1378702023-07-14T15:56:33Z Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation Liu, Zhiyuan Wang, Hui Huang, Pingao Huang, Jianping Zhang, Yu Wang, Yuanyuan Yu, Mei Chen, Shixiong Qi, Dianpeng Wang, Ting Jiang, Ying Chen, Geng Hu, Guoyu Li, Wenlong Yu, Jiancan Luo, Yifei Loh, Xian Jun Liedberg, Bo Li, Guanglin Chen, Xiaodong School of Materials Science & Engineering Innovative Centre for Flexible Devices (iFLEX) Max Planck-NTU Joint Lab for Artificial Senses Engineering::Materials Adhesion Interlocking Effect Stretchable conductors are the basic units of advanced flexible electronic devices, such as skin‐like sensors, stretchable batteries and soft actuators. Current fabrication strategies are mainly focused on the stretchability of the conductor with less emphasis on the huge mismatch of the conductive material and polymeric substrate, which results in stability issues during long‐term use. Thermal‐radiation‐assisted metal encapsulation is reported to construct an interlocking layer between polydimethylsiloxane (PDMS) and gold by employing a semipolymerized PDMS substrate to encapsulate the gold clusters/atoms during thermal deposition. The stability of the stretchable conductor is significantly enhanced based on the interlocking effect of metal and polymer, with high interfacial adhesion (>2 MPa) and cyclic stability (>10 000 cycles). Also, the conductor exhibits superior properties such as high stretchability (>130%) and large active surface area (>5:1 effective surface area/geometrical area). It is noted that this method can be easily used to fabricate such a stretchable conductor in a wafer‐scale format through a one‐step process. As a proof of concept, both long‐term implantation in an animal model to monitor intramuscular electric signals and on human skin for detection of biosignals are demonstrated. This design approach brings about a new perspective on the exploration of stretchable conductors for biomedical applications. NRF (Natl Research Foundation, S’pore) ASTAR (Agency for Sci., Tech. and Research, S’pore) Accepted version 2020-04-17T01:51:42Z 2020-04-17T01:51:42Z 2019 Journal Article Liu, Z., Wang, H., Huang, P., Huang, J., Zhang, Y., Wang, Y., . . . Chen, X. (2019). Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation. Advanced materials, 31(35), 1901360-. doi:10.1002/adma.201901360 0935-9648 https://hdl.handle.net/10356/137870 10.1002/adma.201901360 31282042 2-s2.0-85068690636 35 31 en Advanced materials This is the peer reviewed version of the following article: Liu, Z., Wang, H., Huang, P., Huang, J., Zhang, Y., Wang, Y., . . . Chen, X. (2019). Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation. Advanced materials, 31(35), 1901360-. doi:10.1002/adma.201901360, which has been published in final form at https://doi.org/10.1002/adma.201901360. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Materials
Adhesion
Interlocking Effect
spellingShingle Engineering::Materials
Adhesion
Interlocking Effect
Liu, Zhiyuan
Wang, Hui
Huang, Pingao
Huang, Jianping
Zhang, Yu
Wang, Yuanyuan
Yu, Mei
Chen, Shixiong
Qi, Dianpeng
Wang, Ting
Jiang, Ying
Chen, Geng
Hu, Guoyu
Li, Wenlong
Yu, Jiancan
Luo, Yifei
Loh, Xian Jun
Liedberg, Bo
Li, Guanglin
Chen, Xiaodong
Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
description Stretchable conductors are the basic units of advanced flexible electronic devices, such as skin‐like sensors, stretchable batteries and soft actuators. Current fabrication strategies are mainly focused on the stretchability of the conductor with less emphasis on the huge mismatch of the conductive material and polymeric substrate, which results in stability issues during long‐term use. Thermal‐radiation‐assisted metal encapsulation is reported to construct an interlocking layer between polydimethylsiloxane (PDMS) and gold by employing a semipolymerized PDMS substrate to encapsulate the gold clusters/atoms during thermal deposition. The stability of the stretchable conductor is significantly enhanced based on the interlocking effect of metal and polymer, with high interfacial adhesion (>2 MPa) and cyclic stability (>10 000 cycles). Also, the conductor exhibits superior properties such as high stretchability (>130%) and large active surface area (>5:1 effective surface area/geometrical area). It is noted that this method can be easily used to fabricate such a stretchable conductor in a wafer‐scale format through a one‐step process. As a proof of concept, both long‐term implantation in an animal model to monitor intramuscular electric signals and on human skin for detection of biosignals are demonstrated. This design approach brings about a new perspective on the exploration of stretchable conductors for biomedical applications.
author2 School of Materials Science & Engineering
author_facet School of Materials Science & Engineering
Liu, Zhiyuan
Wang, Hui
Huang, Pingao
Huang, Jianping
Zhang, Yu
Wang, Yuanyuan
Yu, Mei
Chen, Shixiong
Qi, Dianpeng
Wang, Ting
Jiang, Ying
Chen, Geng
Hu, Guoyu
Li, Wenlong
Yu, Jiancan
Luo, Yifei
Loh, Xian Jun
Liedberg, Bo
Li, Guanglin
Chen, Xiaodong
format Article
author Liu, Zhiyuan
Wang, Hui
Huang, Pingao
Huang, Jianping
Zhang, Yu
Wang, Yuanyuan
Yu, Mei
Chen, Shixiong
Qi, Dianpeng
Wang, Ting
Jiang, Ying
Chen, Geng
Hu, Guoyu
Li, Wenlong
Yu, Jiancan
Luo, Yifei
Loh, Xian Jun
Liedberg, Bo
Li, Guanglin
Chen, Xiaodong
author_sort Liu, Zhiyuan
title Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
title_short Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
title_full Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
title_fullStr Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
title_full_unstemmed Highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
title_sort highly stable and stretchable conductive films through thermal‐radiation‐assisted metal encapsulation
publishDate 2020
url https://hdl.handle.net/10356/137870
_version_ 1772825489248878592

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