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W. Ding, Changsheng Wu, Yunlong Zi, Haiyang Zou, Jiyu Wang, Jia Cheng, A. Wang, Zhong Wang (2018)
Self-powered wireless optical transmission of mechanical agitation signalsNano Energy, 47
So Kim, Sangsik Park, H. Park, Do Park, Youngjin Jeong, Do Kim (2015)
Highly Sensitive and Multimodal All‐Carbon Skin Sensors Capable of Simultaneously Detecting Tactile and Biological StimuliAdvanced Materials, 27
Xuchun Gui, A. Cao, Jinquan Wei, Hongbian Li, Y. Jia, Zhen Li, Lili Fan, Kunlin Wang, Hongwei Zhu, De-hai Wu (2010)
Soft, highly conductive nanotube sponges and composites with controlled compressibility.ACS nano, 4 4
Chuang Wang, David Hwang, Zhibin Yu, K. Takei, Junwoo Park, Teresa Chen, Biwu Ma, A. Javey (2013)
User-interactive electronic skin for instantaneous pressure visualization.Nature materials, 12 10
Qilin Hua, Junlu Sun, Haitao Liu, Rongrong Bao, Ruomeng Yu, J. Zhai, Caofeng Pan, Zhong Wang (2018)
Skin-inspired highly stretchable and conformable matrix networks for multifunctional sensingNature Communications, 9
Zhenhua Tang, Shuhai Jia, Fei Wang, Changsheng Bian, Yuyu Chen, Yonglin Wang, Bo Li (2018)
Highly Stretchable Core-Sheath Fibers via Wet-Spinning for Wearable Strain Sensors.ACS applied materials & interfaces, 10 7
Jonghwa Park, Marie Kim, Youngoh Lee, H. Lee, Hyunhyub Ko (2015)
Fingertip skin–inspired microstructured ferroelectric skins discriminate static/dynamic pressure and temperature stimuliScience Advances, 1
Daeshik Kang, P. Pikhitsa, Y. Choi, Chanseok Lee, Sungsoo Shin, Linfeng Piao, Byeonghak Park, K. Suh, Tae‐il Kim, Mansoo Choi (2014)
Ultrasensitive mechanical crack-based sensor inspired by the spider sensory systemNature, 516
Shu Gong, W. Schwalb, Yongwei Wang, Yi Chen, Yue Tang, Jye Si, B. Shirinzadeh, Wenlong Cheng (2014)
A wearable and highly sensitive pressure sensor with ultrathin gold nanowiresNature Communications, 5
Jaehong Lee, Hyukho Kwon, Jungmok Seo, Sera Shin, Ja Koo, Changhyun Pang, Seungbae Son, Jae Kim, Y. Jang, Daeeun Kim, Taeyoon Lee (2015)
Conductive Fiber‐Based Ultrasensitive Textile Pressure Sensor for Wearable ElectronicsAdvanced Materials, 27
Tie Li, Hui Luo, Lin Qin, Xuewen Wang, Zuoping Xiong, Haiyan Ding, Yang Gu, Zheng Liu, Ting Zhang (2016)
Flexible Capacitive Tactile Sensor Based on Micropatterned Dielectric Layer.Small, 12 36
Mengyang Zheng, Wenyang Li, Mengjiao Xu, Ning Xu, Peng Chen, Min Han, B. Xie (2014)
Strain sensors based on chromium nanoparticle arrays.Nanoscale, 6 8
Xiandi Wang, Yufei Zhang, Xiaojia Zhang, Zhihao Huo, Xiaoyi Li, Miaoling Que, Zhengchun Peng, Hui Wang, Caofeng Pan (2018)
A Highly Stretchable Transparent Self‐Powered Triboelectric Tactile Sensor with Metallized Nanofibers for Wearable ElectronicsAdvanced Materials, 30
Yunsik Joo, J. Byun, Narkhyeon Seong, Jewook Ha, Hyunjong Kim, Sangwoo Kim, Taehoon Kim, Hwarim Im, Donghyun Kim, Yongtaek Hong (2015)
Silver nanowire-embedded PDMS with a multiscale structure for a highly sensitive and robust flexible pressure sensor.Nanoscale, 7 14
Lili Wang, Joshua Jackman, Ee‐Lin Tan, J. Park, Michael Potroz, E. Hwang, Nam‐Joon Cho (2017)
High-performance, flexible electronic skin sensor incorporating natural microcapsule actuatorsNano Energy, 36
(1954)
Piezoresistancc effect in germanium and silicon
Sungwon Lee, Amir Reuveny, Jonathan Reeder, Sunghoon Lee, Hanbit Jin, Qihan Liu, T. Yokota, T. Sekitani, Takashi Isoyama, Y. Abe, Z. Suo, T. Someya (2016)
A transparent bending-insensitive pressure sensor.Nature nanotechnology, 11 5
Bin Su, Shu Gong, Zheng Ma, Lim Yap, Wenlong Cheng (2015)
Mimosa-inspired design of a flexible pressure sensor with touch sensitivity.Small, 11 16
Yi Wang, Rong Yang, Zhiwen Shi, Lianchang Zhang, D. Shi, E. Wang, Guangyu Zhang (2011)
Super-elastic graphene ripples for flexible strain sensors.ACS nano, 5 5
Morteza Amjadi, Aekachan Pichitpajongkit, Sangjun Lee, Seunghwa Ryu, I. Park (2014)
Highly stretchable and sensitive strain sensor based on silver nanowire-elastomer nanocomposite.ACS nano, 8 5
Xun Han, Mengxiao Chen, Caofeng Pan, Zhong Wang (2016)
Progress in piezo-phototronic effect enhanced photodetectorsJournal of Materials Chemistry C, 4
Yujie Ding, Jiaqi Zhu, Chunhui Wang, B. Dai, Yuxin Li, Yuyang Qin, Fan Xu, Qingyu Peng, Zhenhuai Yang, J. Bai, Wenxin Cao, Ye Yuan, Yibin Li (2016)
Multifunctional three-dimensional graphene nanoribbons composite spongeCarbon, 104
Wenxi Guo, Chen Xu, G. Zhu, Caofeng Pan, Changjian Lin, Zhong Wang (2012)
Optical-fiber/TiO2-nanowire-arrays hybrid structures with tubular counterelectrode for dye-sensitized solar cellNano Energy, 1
Jonghwa Park, Youngoh Lee, Minjeong Ha, Seungse Cho, Hyunhyub Ko (2016)
Micro/nanostructured surfaces for self-powered and multifunctional electronic skins.Journal of materials chemistry. B, 4 18
Yue Tang, Shu Gong, Yi Chen, Lim Yap, Wenlong Cheng (2014)
Manufacturable conducting rubber ambers and stretchable conductors from copper nanowire aerogel monoliths.ACS nano, 8 6
T. Someya, Y. Kato, T. Sekitani, S. Iba, Y. Noguchi, Y. Murase, H. Kawaguchi, T. Sakurai (2005)
Conformable, flexible, large-area networks of pressure and thermal sensors with organic transistor active matrixes.Proceedings of the National Academy of Sciences of the United States of America, 102 35
Yongchao Tang, Zongbin Zhao, Han Hu, Yang Liu, Xuzhen Wang, Shanke Zhou, J. Qiu (2015)
Highly Stretchable and Ultrasensitive Strain Sensor Based on Reduced Graphene Oxide Microtubes-Elastomer Composite.ACS applied materials & interfaces, 7 49
Weibing Zhong, Qiongzhen Liu, Yongzhi Wu, Yuedan Wang, X. Qing, Mufang Li, Ke Liu, Wenwen Wang, Dong Wang (2016)
A nanofiber based artificial electronic skin with high pressure sensitivity and 3D conformability.Nanoscale, 8 24
Lisa Chen, Benjamin Tee, Alex Chortos, Gregor Schwartz, V. Tse, D. Lipomi, H. Wong, M. McConnell, Zhenan Bao (2014)
Continuous wireless pressure monitoring and mapping with ultra-small passive sensors for health monitoring and critical careNature Communications, 5
Charles Smith (1954)
Piezoresistance Effect in Germanium and SiliconPhysical Review, 94
J. Kong, Nam-Su Jang, S. Kim, Jong-Man Kim (2014)
Simple and rapid micropatterning of conductive carbon composites and its application to elastic strain sensorsCarbon, 77
A. Barlian, W. Park, J. Mallon, A. Rastegar, B. Pruitt (2009)
Review: Semiconductor Piezoresistance for MicrosystemsProceedings of the IEEE, 97
Zongping Chen, W. Ren, Libo Gao, Bilu Liu, S. Pei, Hui‐Ming Cheng (2011)
Three-dimensional flexible and conductive interconnected graphene networks grown by chemical vapour deposition.Nature materials, 10 6
M. Hussain, Y. Choa, K. Niihara (2001)
Conductive rubber materials for pressure sensorsJournal of Materials Science Letters, 20
C. Choong, Mun-Bo Shim, Byoung-Sun Lee, S. Jeon, D. Ko, Tae‐Hyung Kang, Jihyun Bae, Sung Lee, Kyung‐Eun Byun, Jungkyun Im, Yong-Jin Jeong, Chan Park, Jong‐Jin Park, U. Chung (2014)
Highly Stretchable Resistive Pressure Sensors Using a Conductive Elastomeric Composite on a Micropyramid ArrayAdvanced Materials, 26
Mengmeng Liu, Xiong Pu, Chunyan Jiang, Ting Liu, Xin Huang, Libo Chen, Chunhua Du, Jiangman Sun, Weiguo Hu, Zhong Wang (2017)
Large‐Area All‐Textile Pressure Sensors for Monitoring Human Motion and Physiological SignalsAdvanced Materials, 29
D. Lipomi, Michael Vosgueritchian, Benjamin Tee, Sondra Hellstrom, Jennifer Lee, Courtney Fox, Zhenan Bao (2011)
Skin-like pressure and strain sensors based on transparent elastic films of carbon nanotubes.Nature nanotechnology, 6 12
Minghui Cao, Minqiang Wang, Le Li, Hengwei Qiu, M. Padhiar, Zhi Yang (2018)
Wearable rGO-Ag NW@cotton fiber piezoresistive sensor based on the fast charge transport channel provided by Ag nanowireNano Energy
Benjamin Tee, Alex Chortos, Roger Dunn, Gregor Schwartz, E. Eason, Zhenan Bao (2014)
Tunable Flexible Pressure Sensors using Microstructured Elastomer Geometries for Intuitive ElectronicsAdvanced Functional Materials, 24
Ling Qiu, Je Liu, S. Chang, Yanzhe Wu, Dan Li (2012)
Biomimetic superelastic graphene-based cellular monolithsNature Communications, 3
M. Shimojo, A. Namiki, M. Ishikawa, R. Makino, K. Mabuchi (2004)
A tactile sensor sheet using pressure conductive rubber with electrical-wires stitched methodIEEE Sensors Journal, 4
Xuewen Wang, Yang Gu, Zuoping Xiong, Z. Cui, Ting Zhang (2014)
Silk‐Molded Flexible, Ultrasensitive, and Highly Stable Electronic Skin for Monitoring Human Physiological SignalsAdvanced Materials, 26
Å. Vallbo, R. Johansson (1984)
Properties of cutaneous mechanoreceptors in the human hand related to touch sensation.Human neurobiology, 3 1
Jonghwa Park, Youngoh Lee, Jaehyung Hong, Minjeong Ha, Youngdo Jung, Hyuneui Lim, Sung Kim, Hyunhyub Ko (2014)
Giant tunneling piezoresistance of composite elastomers with interlocked microdome arrays for ultrasensitive and multimodal electronic skins.ACS nano, 8 5
T. Someya, T. Sekitani, S. Iba, Y. Kato, H. Kawaguchi, T. Sakurai (2004)
A large-area, flexible pressure sensor matrix with organic field-effect transistors for artificial skin applications.Proceedings of the National Academy of Sciences of the United States of America, 101 27
Lijia Pan, Alex Chortos, Guihua Yu, Yaqun Wang, Scott Isaacson, R. Allen, Yi Shi, R. Dauskardt, Z. Bao (2014)
An ultra-sensitive resistive pressure sensor based on hollow-sphere microstructure induced elasticity in conducting polymer filmNature Communications, 5
Seongwoo Ryu, Phillip Lee, J. Chou, R. Xu, Rong Zhao, A. Hart, Sang-Gook Kim (2015)
Extremely Elastic Wearable Carbon Nanotube Fiber Strain Sensor for Monitoring of Human Motion.ACS nano, 9 6
To mimic the sensing function of human skin, the rational design of force‐sensitive materials is highly required for sensors. Here, a facile design of resistive‐type tactile sensors based on a structured silver nanowire‐polydimethylsiloxane composite is reported for applications in electronic skins and wearable electronics. The composite has a hollow microstructure of interconnected channels, and the inner surface of the channels is a conductive layer consisting of silver nanowires. The sensing function to external force is realized by measuring the resistance change upon deforming. The deforming causes the distance change of silver nanowires and the contact‐area change of the inner surfaces. Such a unique structure promises a robust mechanical property due to the half‐embedded silver nanowires which are free of peeling off, and also makes it possible to control the device sensitivity by its mechanical structure and the elastic property of the polydimethylsiloxane. The results show that the composite has steady‐state responses to various pressures and stretches, even to mouth blowing, a response time of ≈90 ms, and favorable repeatability over 2000 cycles of bending/unbending. The 3D structure enables pressing, bending, pulling and torsional force sensing, and promises real‐time monitoring of various human motions ranging from blood pulses to joint movements.
Advanced Materials Technologies – Wiley
Published: Mar 1, 2019
Keywords: ; ; ;
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