Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles
Stretchable conductors are vital and indispensable components in soft electronic systems. The development for stretchable conductors has been highly motivated with different approaches established to address the dilemma in the conductivity and stretchability trade-offs to some extent. Here, a new st...
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sg-ntu-dr.10356-1387812021-02-15T05:51:15Z Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles Wang, Jiangxin Cai, Guofa Li, Shaohui Gao, Dace Xiong, Jiaqing Lee, Pooi See School of Materials Science & Engineering Engineering::Materials 3D Printing Electronic Skin Stretchable conductors are vital and indispensable components in soft electronic systems. The development for stretchable conductors has been highly motivated with different approaches established to address the dilemma in the conductivity and stretchability trade-offs to some extent. Here, a new strategy to achieve superelastic conductors with high conductivity and stable electrical performance under stretching is reported. It is demonstrated that by electrically anchoring conductive fillers with eutectic gallium indium particles (EGaInPs), significant improvement in stretchability and durability can be achieved in stretchable conductors. Different from the strategy of modulating the chemical interactions between the conductive fillers and host polymers, the EGaInPs provide dynamic and robust electrical anchors between the conductive fillers. A superelastic conductor which can achieve a high stretchability with 1000% strain at initial conductivity of 8331 S cm-1 and excellent cycling durability with about eight times resistance change (compared to the initial resistance at 0% strain before stretching) after reversibly stretching to 800% strain for 10 000 times is demonstrated. Applications of the superelastic conductor in an interactive soft touch device and a stretchable light-emitting system are also demonstrated, featuring its promising applications in soft robotics or soft and interactive human-machine interfaces. National Research Foundation (NRF) The authors thank Dr. M. Lin, Dr. J. Xiong, Dr. P, Cui, Q. Kai, and X. Chen for their valuable discussions. This work was financially supported by the National Research Foundation Competitive Research Programme (Award No. NRF-CRP-13-2014-02), and the NRF Investigatorship (NRFI) (Award No. NRF-NRFI2016-05). 2020-05-12T09:16:41Z 2020-05-12T09:16:41Z 2018 Journal Article Wang, J., Cai, G., Li, S., Gao, D., Xiong, J., & Lee, P. S. (2018). Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles. Advanced Materials, 30(16), 1706157-. doi:10.1002/adma.201706157 0935-9648 https://hdl.handle.net/10356/138781 10.1002/adma.201706157 29512208 2-s2.0-85043400161 16 30 en NRF-CRP-13-2014-02 NRF-NRFI2016-05 Advanced Materials © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. This paper was published in Advanced Materials and is made available with permission of WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. |
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Engineering::Materials 3D Printing Electronic Skin Wang, Jiangxin Cai, Guofa Li, Shaohui Gao, Dace Xiong, Jiaqing Lee, Pooi See Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| description |
Stretchable conductors are vital and indispensable components in soft electronic systems. The development for stretchable conductors has been highly motivated with different approaches established to address the dilemma in the conductivity and stretchability trade-offs to some extent. Here, a new strategy to achieve superelastic conductors with high conductivity and stable electrical performance under stretching is reported. It is demonstrated that by electrically anchoring conductive fillers with eutectic gallium indium particles (EGaInPs), significant improvement in stretchability and durability can be achieved in stretchable conductors. Different from the strategy of modulating the chemical interactions between the conductive fillers and host polymers, the EGaInPs provide dynamic and robust electrical anchors between the conductive fillers. A superelastic conductor which can achieve a high stretchability with 1000% strain at initial conductivity of 8331 S cm-1 and excellent cycling durability with about eight times resistance change (compared to the initial resistance at 0% strain before stretching) after reversibly stretching to 800% strain for 10 000 times is demonstrated. Applications of the superelastic conductor in an interactive soft touch device and a stretchable light-emitting system are also demonstrated, featuring its promising applications in soft robotics or soft and interactive human-machine interfaces. |
| author2 |
School of Materials Science & Engineering |
| author_facet |
School of Materials Science & Engineering Wang, Jiangxin Cai, Guofa Li, Shaohui Gao, Dace Xiong, Jiaqing Lee, Pooi See |
| format |
Article |
| author |
Wang, Jiangxin Cai, Guofa Li, Shaohui Gao, Dace Xiong, Jiaqing Lee, Pooi See |
| author_sort |
Wang, Jiangxin |
| title |
Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| title_short |
Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| title_full |
Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| title_fullStr |
Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| title_full_unstemmed |
Printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| title_sort |
printable superelastic conductors with extreme stretchability and robust cycling endurance enabled by liquid-metal particles |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/138781 |
| _version_ |
1696984376493998080 |