Electro-mechano responsive elastomers with self-tunable conductivity and stiffness

Guolin Yun; Tim Cole; Yuxin Zhang; Jiahao Zheng; Shuaishuai Sun; Yiming Ou-yang; Jian Shu; Hongda Lu; Qingtian Zhang; Yongjing Wang; Duc Pham; Tawfique Hasan; Weihua Li; Shiwu Zhang; Shi-Yang Tang

doi:10.1126/sciadv.adf1141

Electro-mechano responsive elastomers with self-tunable conductivity and stiffness

Guolin Yun, Tim Cole, Yuxin Zhang, Jiahao Zheng, Shuaishuai Sun, Yiming Ou-yang, Jian Shu, Hongda Lu, Qingtian Zhang, Yongjing Wang, Duc Pham, Tawfique Hasan, Weihua Li^*, Shiwu Zhang^*, Shi-Yang Tang^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Materials with programmable conductivity and stiffness offer new design opportunities for next-generation engineered systems in soft robotics and electronic devices. However, existing approaches fail to harness variable electrical and mechanical properties synergistically and lack the ability to self-respond to environmental changes. We report an electro-mechano responsive Field’s metal hybrid elastomer exhibiting variable and tunable conductivity, strain sensitivity, and stiffness. By synergistically harnessing these properties, we demonstrate two applications with over an order of magnitude performance improvement compared to state-of-the-art, including a self-triggered multiaxis compliance compensator for robotic manipulators, and a resettable, highly compact, and fast current-limiting fuse with an adjustable fusing current. We envisage that the extraordinary electromechanical properties of our hybrid elastomer will bring substantial advancements in resilient robotic systems, intelligent instruments, and flexible electronics.

Original language	English
Article number	eadf1141
Number of pages	9
Journal	Science Advances
Volume	9
Issue number	4
DOIs	https://doi.org/10.1126/sciadv.adf1141
Publication status	Published - 25 Jan 2023

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YunG2023ElectroFinal published version, 1.42 MBLicence: Creative Commons: Attribution (CC BY)

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Engineering & Physical Science Research Council
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Cite this

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title = "Electro-mechano responsive elastomers with self-tunable conductivity and stiffness",

abstract = "Materials with programmable conductivity and stiffness offer new design opportunities for next-generation engineered systems in soft robotics and electronic devices. However, existing approaches fail to harness variable electrical and mechanical properties synergistically and lack the ability to self-respond to environmental changes. We report an electro-mechano responsive Field{\textquoteright}s metal hybrid elastomer exhibiting variable and tunable conductivity, strain sensitivity, and stiffness. By synergistically harnessing these properties, we demonstrate two applications with over an order of magnitude performance improvement compared to state-of-the-art, including a self-triggered multiaxis compliance compensator for robotic manipulators, and a resettable, highly compact, and fast current-limiting fuse with an adjustable fusing current. We envisage that the extraordinary electromechanical properties of our hybrid elastomer will bring substantial advancements in resilient robotic systems, intelligent instruments, and flexible electronics.",

author = "Guolin Yun and Tim Cole and Yuxin Zhang and Jiahao Zheng and Shuaishuai Sun and Yiming Ou-yang and Jian Shu and Hongda Lu and Qingtian Zhang and Yongjing Wang and Duc Pham and Tawfique Hasan and Weihua Li and Shiwu Zhang and Shi-Yang Tang",

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doi = "10.1126/sciadv.adf1141",

language = "English",

volume = "9",

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T1 - Electro-mechano responsive elastomers with self-tunable conductivity and stiffness

AU - Yun, Guolin

AU - Cole, Tim

AU - Zhang, Yuxin

AU - Zheng, Jiahao

AU - Sun, Shuaishuai

AU - Ou-yang, Yiming

AU - Shu, Jian

AU - Lu, Hongda

AU - Zhang, Qingtian

AU - Wang, Yongjing

AU - Pham, Duc

AU - Hasan, Tawfique

AU - Li, Weihua

AU - Zhang, Shiwu

AU - Tang, Shi-Yang

PY - 2023/1/25

Y1 - 2023/1/25

N2 - Materials with programmable conductivity and stiffness offer new design opportunities for next-generation engineered systems in soft robotics and electronic devices. However, existing approaches fail to harness variable electrical and mechanical properties synergistically and lack the ability to self-respond to environmental changes. We report an electro-mechano responsive Field’s metal hybrid elastomer exhibiting variable and tunable conductivity, strain sensitivity, and stiffness. By synergistically harnessing these properties, we demonstrate two applications with over an order of magnitude performance improvement compared to state-of-the-art, including a self-triggered multiaxis compliance compensator for robotic manipulators, and a resettable, highly compact, and fast current-limiting fuse with an adjustable fusing current. We envisage that the extraordinary electromechanical properties of our hybrid elastomer will bring substantial advancements in resilient robotic systems, intelligent instruments, and flexible electronics.

AB - Materials with programmable conductivity and stiffness offer new design opportunities for next-generation engineered systems in soft robotics and electronic devices. However, existing approaches fail to harness variable electrical and mechanical properties synergistically and lack the ability to self-respond to environmental changes. We report an electro-mechano responsive Field’s metal hybrid elastomer exhibiting variable and tunable conductivity, strain sensitivity, and stiffness. By synergistically harnessing these properties, we demonstrate two applications with over an order of magnitude performance improvement compared to state-of-the-art, including a self-triggered multiaxis compliance compensator for robotic manipulators, and a resettable, highly compact, and fast current-limiting fuse with an adjustable fusing current. We envisage that the extraordinary electromechanical properties of our hybrid elastomer will bring substantial advancements in resilient robotic systems, intelligent instruments, and flexible electronics.

U2 - 10.1126/sciadv.adf1141

DO - 10.1126/sciadv.adf1141

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VL - 9

JO - Science Advances

JF - Science Advances

IS - 4

M1 - eadf1141

ER -

Electro-mechano responsive elastomers with self-tunable conductivity and stiffness

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Projects

Self-learning robotics for industrial contact-rich tasks (ATARI): enabling smart learning in automated disassembly

Programmable Microwave Hardware Based on Liquid Wire (PROGRAMMABLE)

Investigating liquid metal enabled microelectromechanical systems (LM-MEMS) for driving biomimetic origami robots

Automatic disassembly replanning for autonomous remanufacturing

Cite this