Ultra-sensitive strain sensors based on piezoresistive nanographene films

Jing Zhao; Congli He; Rong Yang; Zhiwen Shi; Meng Cheng; Wei Yang; Guibai Xie; Duoming Wang; Dongxia Shi; Guangyu Zhang

doi:10.1063/1.4742331

Ultra-sensitive strain sensors based on piezoresistive nanographene films

Jing Zhao, Congli He, Rong Yang, Zhiwen Shi, Meng Cheng, Wei Yang, Guibai Xie, Duoming Wang, Dongxia Shi^*, Guangyu Zhang

^*Corresponding author for this work

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

311 Citations (Scopus)

Abstract

Graphene shows promise on strain sensor applications, but the piezoresistive sensitivity of perfect graphene is low due to its weak electrical conductivity response upon structural deformation. In this paper, we used nanographene films for ultra-sensitive strain sensors. The piezoresistive sensitivity of nanographene films with different thicknesses and conductivities was systematically investigated and a nearly inverse proportional correlation was found. A gauge factor over 300, the highest so far for graphene-based strain sensors, was achieved. A charge tunneling model was used to explain the piezoresistive characteristics of nanographene films, which indicates our results provide a different rout toward ultra-sensitive strain sensors.

Original language	English
Article number	063112
Journal	Applied Physics Letters
Volume	101
Issue number	6
DOIs	https://doi.org/10.1063/1.4742331
Publication status	Published - 6 Aug 2012
Externally published	Yes

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abstract = "Graphene shows promise on strain sensor applications, but the piezoresistive sensitivity of perfect graphene is low due to its weak electrical conductivity response upon structural deformation. In this paper, we used nanographene films for ultra-sensitive strain sensors. The piezoresistive sensitivity of nanographene films with different thicknesses and conductivities was systematically investigated and a nearly inverse proportional correlation was found. A gauge factor over 300, the highest so far for graphene-based strain sensors, was achieved. A charge tunneling model was used to explain the piezoresistive characteristics of nanographene films, which indicates our results provide a different rout toward ultra-sensitive strain sensors.",

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AU - He, Congli

AU - Yang, Rong

AU - Shi, Zhiwen

AU - Cheng, Meng

AU - Yang, Wei

AU - Xie, Guibai

AU - Wang, Duoming

AU - Shi, Dongxia

AU - Zhang, Guangyu

PY - 2012/8/6

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AB - Graphene shows promise on strain sensor applications, but the piezoresistive sensitivity of perfect graphene is low due to its weak electrical conductivity response upon structural deformation. In this paper, we used nanographene films for ultra-sensitive strain sensors. The piezoresistive sensitivity of nanographene films with different thicknesses and conductivities was systematically investigated and a nearly inverse proportional correlation was found. A gauge factor over 300, the highest so far for graphene-based strain sensors, was achieved. A charge tunneling model was used to explain the piezoresistive characteristics of nanographene films, which indicates our results provide a different rout toward ultra-sensitive strain sensors.

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Ultra-sensitive strain sensors based on piezoresistive nanographene films

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