Enhancing the Matrix Addressing of Flexible Sensory Arrays by a Highly Nonlinear Threshold Switch

Ming Wang; Wei Wang; Wan Ru Leow; Changjin Wan; Geng Chen; Yi Zeng; Jiancan Yu; Yaqing Liu; Pingqiang Cai; Hong Wang; Daniele Ielmini; Xiaodong Chen

doi:10.1002/adma.201802516

Enhancing the Matrix Addressing of Flexible Sensory Arrays by a Highly Nonlinear Threshold Switch

Ming Wang, Wei Wang, Wan Ru Leow, Changjin Wan, Geng Chen, Yi Zeng, Jiancan Yu, Yaqing Liu, Pingqiang Cai, Hong Wang, Daniele Ielmini^*, Xiaodong Chen

^*Corresponding author for this work

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

76 Citations (Scopus)

Abstract

The increasing need for smart systems in healthcare, wearable, and soft robotics is creating demand for low-power sensory circuits that can detect pressure, temperature, strain, and other local variables. Among the most critical requirements, the matrix circuitry to address the individual sensor device must be sensitive, immune to disturbances, and flexible within a high-density sensory array. Here, a strategy is reported to enhance the matrix addressing of a fully integrated flexible sensory array with an improvement of 10⁸ fold in the maximum readout value of impedance by a bidirectional threshold switch. The threshold switch shows high flexibility (bendable to a radius of about 1 mm) and a high nonlinearity of ≈10¹⁰ by using a nanocontact structure strategy, which is revealed and validated by molecular dynamics simulations and experiments at variable mechanical stress. Such a flexible electronic switch enables a new generation of large-scale flexible and stretchable electronic and optoelectronic systems.

Original language	English
Article number	1802516
Journal	Advanced Materials
Volume	30
Issue number	33
DOIs	https://doi.org/10.1002/adma.201802516
Publication status	Published - Aug 16 2018
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

ASJC Scopus Subject Areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

Keywords

flexible sensory arrays
flexible threshold switches
highly nonlinear
matrix addressing
nanocontacts

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10.1002/adma.201802516

Cite this

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abstract = "The increasing need for smart systems in healthcare, wearable, and soft robotics is creating demand for low-power sensory circuits that can detect pressure, temperature, strain, and other local variables. Among the most critical requirements, the matrix circuitry to address the individual sensor device must be sensitive, immune to disturbances, and flexible within a high-density sensory array. Here, a strategy is reported to enhance the matrix addressing of a fully integrated flexible sensory array with an improvement of 108 fold in the maximum readout value of impedance by a bidirectional threshold switch. The threshold switch shows high flexibility (bendable to a radius of about 1 mm) and a high nonlinearity of ≈1010 by using a nanocontact structure strategy, which is revealed and validated by molecular dynamics simulations and experiments at variable mechanical stress. Such a flexible electronic switch enables a new generation of large-scale flexible and stretchable electronic and optoelectronic systems.",

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AU - Leow, Wan Ru

AU - Wan, Changjin

AU - Chen, Geng

AU - Zeng, Yi

AU - Yu, Jiancan

AU - Liu, Yaqing

AU - Cai, Pingqiang

AU - Wang, Hong

AU - Ielmini, Daniele

AU - Chen, Xiaodong

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N2 - The increasing need for smart systems in healthcare, wearable, and soft robotics is creating demand for low-power sensory circuits that can detect pressure, temperature, strain, and other local variables. Among the most critical requirements, the matrix circuitry to address the individual sensor device must be sensitive, immune to disturbances, and flexible within a high-density sensory array. Here, a strategy is reported to enhance the matrix addressing of a fully integrated flexible sensory array with an improvement of 108 fold in the maximum readout value of impedance by a bidirectional threshold switch. The threshold switch shows high flexibility (bendable to a radius of about 1 mm) and a high nonlinearity of ≈1010 by using a nanocontact structure strategy, which is revealed and validated by molecular dynamics simulations and experiments at variable mechanical stress. Such a flexible electronic switch enables a new generation of large-scale flexible and stretchable electronic and optoelectronic systems.

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Enhancing the Matrix Addressing of Flexible Sensory Arrays by a Highly Nonlinear Threshold Switch

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

Access to Document

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