Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites

Jianfeng Wu; Ziyuan Ma; Zheng Hao; John Tao Zhang; Pengfei Sun; Minghao Zhang; Yangkun Liu; Yushu Cheng; Yu Li; Bo Zhong; Tao Zhang; Long Xia; Wang Yao; Xiaoxiao Huang; Huatao Wang; Haiping Liu; Feng Yan; Chien En Hsu; Guozhong Xing

doi:10.1021/acsanm.8b01926

Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites

Jianfeng Wu
, Ziyuan Ma
, Zheng Hao
, John Tao Zhang
, Pengfei Sun
, Minghao Zhang
, Yangkun Liu
, Yushu Cheng
, Yu Li
, Bo Zhong
, Tao Zhang
, Long Xia
, Wang Yao
, Xiaoxiao Huang
, Huatao Wang^*
, Haiping Liu
, Feng Yan
, Chien En Hsu
, Guozhong Xing

^*Corresponding author for this work

School of Materials Science and Engineering, Harbin Institute of Technology Weihai
Weihai Engineering Research Center of Graphite Deep-processing Technology
Weihai No.1 High School
China Aerospace Science and Technology Corporation
Harbin Institute of Technology
University of Alabama
United Microelectronics Corporation

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

52 Scopus citations

Abstract

Flexible and stretchable electronics, e.g., graphite-nanoplatelet-based (GNP-based) nanocomposite devices, have attracted great interest due to their potential application in health care, robotics, and mechatronics technology. However, the deficient sensors with manipulation of low sensitivity, sluggish responsivity, sophisticated fabrication process, and poor repeatability notoriously limit their industrial applications. For an enhancement in the spontaneous sensitivity, flexibility, and wearability in GNP-based strain sensors, in this report, synergistic crack and elastic effect engineering is employed and in turn significantly enhances the sensitivity with a gauge factor of 20 at a strain of 30% and the stability in our developed sheath-core fiber (SCF) strain sensors. Upon reliable device integration, it is demonstrated that the developed SCF strain sensor could detect the movement of a human joint effectively with generating a resistance change rate Î"R/R₀ up to 600%. Furthermore, a controlling device system based on the SCF strain sensor has been manufactured at the circuit level to realize the real-time control of a robot hand, such as copying gestures and playing piano.

Original language	English
Pages (from-to)	750-759
Number of pages	10
Journal	ACS Applied Nano Materials
Volume	2
Issue number	2
DOIs	https://doi.org/10.1021/acsanm.8b01926
State	Published - 22 Feb 2019
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

crack and elastic effects
graphite nanoplatelets (GNPs)
robotic mechatronics
sheath-core structure
strain sensors

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10.1021/acsanm.8b01926

Cite this

Wu, J., Ma, Z., Hao, Z., Zhang, J. T., Sun, P., Zhang, M., Liu, Y., Cheng, Y., Li, Y., Zhong, B., Zhang, T., Xia, L., Yao, W., Huang, X., Wang, H., Liu, H., Yan, F., Hsu, C. E., & Xing, G. (2019). Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites. ACS Applied Nano Materials, 2(2), 750-759. https://doi.org/10.1021/acsanm.8b01926

@article{8c37691bda434073a52a33bf97e5730b,

title = "Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites",

abstract = "Flexible and stretchable electronics, e.g., graphite-nanoplatelet-based (GNP-based) nanocomposite devices, have attracted great interest due to their potential application in health care, robotics, and mechatronics technology. However, the deficient sensors with manipulation of low sensitivity, sluggish responsivity, sophisticated fabrication process, and poor repeatability notoriously limit their industrial applications. For an enhancement in the spontaneous sensitivity, flexibility, and wearability in GNP-based strain sensors, in this report, synergistic crack and elastic effect engineering is employed and in turn significantly enhances the sensitivity with a gauge factor of 20 at a strain of 30\% and the stability in our developed sheath-core fiber (SCF) strain sensors. Upon reliable device integration, it is demonstrated that the developed SCF strain sensor could detect the movement of a human joint effectively with generating a resistance change rate {\^I}{"}R/R0 up to 600\%. Furthermore, a controlling device system based on the SCF strain sensor has been manufactured at the circuit level to realize the real-time control of a robot hand, such as copying gestures and playing piano.",

keywords = "crack and elastic effects, graphite nanoplatelets (GNPs), robotic mechatronics, sheath-core structure, strain sensors",

author = "Jianfeng Wu and Ziyuan Ma and Zheng Hao and Zhang, \{John Tao\} and Pengfei Sun and Minghao Zhang and Yangkun Liu and Yushu Cheng and Yu Li and Bo Zhong and Tao Zhang and Long Xia and Wang Yao and Xiaoxiao Huang and Huatao Wang and Haiping Liu and Feng Yan and Hsu, \{Chien En\} and Guozhong Xing",

note = "Publisher Copyright: {\textcopyright} 2019 American Chemical Society.",

year = "2019",

month = feb,

day = "22",

doi = "10.1021/acsanm.8b01926",

language = "英语",

volume = "2",

pages = "750--759",

journal = "ACS Applied Nano Materials",

issn = "2574-0970",

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Wu, J, Ma, Z, Hao, Z, Zhang, JT, Sun, P, Zhang, M, Liu, Y, Cheng, Y, Li, Y, Zhong, B , Zhang, T , Xia, L, Yao, W, Huang, X , Wang, H, Liu, H, Yan, F, Hsu, CE & Xing, G 2019, 'Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites', ACS Applied Nano Materials, vol. 2, no. 2, pp. 750-759. https://doi.org/10.1021/acsanm.8b01926

TY - JOUR

T1 - Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites

AU - Wu, Jianfeng

AU - Ma, Ziyuan

AU - Hao, Zheng

AU - Zhang, John Tao

AU - Sun, Pengfei

AU - Zhang, Minghao

AU - Liu, Yangkun

AU - Cheng, Yushu

AU - Li, Yu

AU - Zhong, Bo

AU - Zhang, Tao

AU - Xia, Long

AU - Yao, Wang

AU - Huang, Xiaoxiao

AU - Wang, Huatao

AU - Liu, Haiping

AU - Yan, Feng

AU - Hsu, Chien En

AU - Xing, Guozhong

PY - 2019/2/22

Y1 - 2019/2/22

N2 - Flexible and stretchable electronics, e.g., graphite-nanoplatelet-based (GNP-based) nanocomposite devices, have attracted great interest due to their potential application in health care, robotics, and mechatronics technology. However, the deficient sensors with manipulation of low sensitivity, sluggish responsivity, sophisticated fabrication process, and poor repeatability notoriously limit their industrial applications. For an enhancement in the spontaneous sensitivity, flexibility, and wearability in GNP-based strain sensors, in this report, synergistic crack and elastic effect engineering is employed and in turn significantly enhances the sensitivity with a gauge factor of 20 at a strain of 30% and the stability in our developed sheath-core fiber (SCF) strain sensors. Upon reliable device integration, it is demonstrated that the developed SCF strain sensor could detect the movement of a human joint effectively with generating a resistance change rate Î"R/R0 up to 600%. Furthermore, a controlling device system based on the SCF strain sensor has been manufactured at the circuit level to realize the real-time control of a robot hand, such as copying gestures and playing piano.

AB - Flexible and stretchable electronics, e.g., graphite-nanoplatelet-based (GNP-based) nanocomposite devices, have attracted great interest due to their potential application in health care, robotics, and mechatronics technology. However, the deficient sensors with manipulation of low sensitivity, sluggish responsivity, sophisticated fabrication process, and poor repeatability notoriously limit their industrial applications. For an enhancement in the spontaneous sensitivity, flexibility, and wearability in GNP-based strain sensors, in this report, synergistic crack and elastic effect engineering is employed and in turn significantly enhances the sensitivity with a gauge factor of 20 at a strain of 30% and the stability in our developed sheath-core fiber (SCF) strain sensors. Upon reliable device integration, it is demonstrated that the developed SCF strain sensor could detect the movement of a human joint effectively with generating a resistance change rate Î"R/R0 up to 600%. Furthermore, a controlling device system based on the SCF strain sensor has been manufactured at the circuit level to realize the real-time control of a robot hand, such as copying gestures and playing piano.

KW - crack and elastic effects

KW - graphite nanoplatelets (GNPs)

KW - robotic mechatronics

KW - sheath-core structure

KW - strain sensors

UR - https://www.scopus.com/pages/publications/85070735771

U2 - 10.1021/acsanm.8b01926

DO - 10.1021/acsanm.8b01926

M3 - 文章

AN - SCOPUS:85070735771

SN - 2574-0970

VL - 2

SP - 750

EP - 759

JO - ACS Applied Nano Materials

JF - ACS Applied Nano Materials

IS - 2

ER -

Sheath-Core Fiber Strain Sensors Driven by in-Situ Crack and Elastic Effects in Graphite Nanoplate Composites

Abstract

UN SDGs

Keywords

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