Recent Progress in Flexible Pressure Sensors Based Electronic Skin

In recent years, implantable electronics, electronic skin (e‐skin), and flexible wearable devices have been developed due to their extensive applications in health monitoring, intelligent robots, and human disease treatment. Tactile sensors are the keys necessary to build skin‐inspired electronics....

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Published inAdvanced engineering materials Vol. 23; no. 5
Main Authors Pierre Claver, Uzabakiriho, Zhao, Gang
Format Journal Article
LanguageEnglish
Published 01.05.2021
Subjects
capacitive
electronic skin
piezoelectrics
piezoresistive
pressure sensors
triboelectrics
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Abstract In recent years, implantable electronics, electronic skin (e‐skin), and flexible wearable devices have been developed due to their extensive applications in health monitoring, intelligent robots, and human disease treatment. Tactile sensors are the keys necessary to build skin‐inspired electronics. This article reviews the latest progress of e‐skin‐based flexible pressure sensors, such as piezoresistivity, capacitance, triboelectricity, and piezoelectricity from 2018 up to now. The working principles, structure design, active materials, and performance of numerous flexible pressure sensors are covered in detail. Finally, insights are provided and challenges and future perspectives of flexible pressure sensors in practical applications are discussed. This article reviews the latest progress of electronic skin based flexible pressure sensors, such as piezoresistivity, capacitance, triboelectric, and piezoelectricity. The working principles, structure design, active materials, and performance of numerous flexible pressure sensors are covered in detail. Finally, insights are provided and challenges and future perspectives of flexible pressure sensors in practical applications are discussed.
AbstractList In recent years, implantable electronics, electronic skin (e‐skin), and flexible wearable devices have been developed due to their extensive applications in health monitoring, intelligent robots, and human disease treatment. Tactile sensors are the keys necessary to build skin‐inspired electronics. This article reviews the latest progress of e‐skin‐based flexible pressure sensors, such as piezoresistivity, capacitance, triboelectricity, and piezoelectricity from 2018 up to now. The working principles, structure design, active materials, and performance of numerous flexible pressure sensors are covered in detail. Finally, insights are provided and challenges and future perspectives of flexible pressure sensors in practical applications are discussed. This article reviews the latest progress of electronic skin based flexible pressure sensors, such as piezoresistivity, capacitance, triboelectric, and piezoelectricity. The working principles, structure design, active materials, and performance of numerous flexible pressure sensors are covered in detail. Finally, insights are provided and challenges and future perspectives of flexible pressure sensors in practical applications are discussed.
Author Pierre Claver, Uzabakiriho
Zhao, Gang
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  orcidid: 0000-0002-0201-1825
  surname: Zhao
  fullname: Zhao, Gang
  email: zhaog@ustc.edu.cn
  organization: University of Science and Technology of China
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Snippet In recent years, implantable electronics, electronic skin (e‐skin), and flexible wearable devices have been developed due to their extensive applications in...
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SubjectTerms capacitive
electronic skin
piezoelectrics
piezoresistive
pressure sensors
triboelectrics
Title Recent Progress in Flexible Pressure Sensors Based Electronic Skin
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fadem.202001187
Volume 23
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