Yan Zhong scite author profile

Recent research achievements for flexible pressure sensors have promoted promising applications, such as human health detection and intelligent robotics. However, striking a balance between sensitivity and linear detection range is still a challenge. In this paper, a dual conductive layer dome (DCLD) structure, where a silver (Ag) nanowire layer is used as a highly conductive layer and the composite layer of carbon black nanoparticles and polydimethylsiloxane (CPDMS) serves as a low conductive layer, is fabricated with a scratch coating process followed by dip-coating and vacuum adsorption. Benefitting from the dual conductive layer design, the sensitivity of the DCLD sensor reaches 51.7 kPa −1 over an ultrawide pressure of 0.01−250 kPa, which is far better than the CPDMS single conductive layer dome (SCLD). The circuit models of DCLD and SCLD are proposed to disclose their working mechanism. The effects of carbon black nanoparticle ratio in CPDMS and the structural matching between the DCLD structure and electrode on the sensor's performance are explored. The long-cycle stability of DCLD sensors with different fabrication methods is also compared. Additionally, it has been demonstrated that the sensor is efficient in monitoring human motion, such as finger joint flexion, pulse pulses, and human breathing, showing potential in the field of human health monitoring.

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Porous conductive electrode for highly sensitive flexible capacitive pressure sensor over a wide range

Zhong

Gu²,

Wu³

et al. 2023

Journal of Alloys and Compounds

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High-performance flexible self-powered triboelectric pressure sensor based on chemically modified micropatterned PDMS film

Zhong

Wang

Liu

et al. 2023

Sensors and Actuators A: Physical

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Tough hydrogel–elastomer hybrids hydrophobically regulated by an MXene for motion monitoring in harsh environments

Dai

Zhang

et al. 2023

J. Mater. Chem. C

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Flexible, high-sensitive and multifunctional wearable sensor based on the dual bioinspired spinosum microstructure of carbon nanotube/carbon black-coated polydimethylsiloxane film

et al. 2023

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Yan Zhong

Ag Nanowire/CPDMS Dual Conductive Layer Dome-Based Flexible Pressure Sensor with High Sensitivity and a Wide Linear Range

Porous conductive electrode for highly sensitive flexible capacitive pressure sensor over a wide range

High-performance flexible self-powered triboelectric pressure sensor based on chemically modified micropatterned PDMS film

Tough hydrogel–elastomer hybrids hydrophobically regulated by an MXene for motion monitoring in harsh environments

Flexible, high-sensitive and multifunctional wearable sensor based on the dual bioinspired spinosum microstructure of carbon nanotube/carbon black-coated polydimethylsiloxane film

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