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

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

Flexible capacitive pressure sensors have aroused widespread concern due to their promising application in wearable electronics. However, the trade-off between sensitivity and response range is yet to be resolved. Herein, flexible capacitive pressure sensors are developed based on high concentration...

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Bibliographic Details
Published in:Journal of alloys and compounds Vol. 934; p. 167919
Main Authors: Zhong, Yan, Gu, Fucheng, Wu, Longgang, Wang, Jiaqi, Dai, Shengping, Zhu, Hao, Cheng, Guanggui, Ding, Jianning
Format: Journal Article
Language:English
Published: Elsevier B.V 10-02-2023
Subjects:
Carbon nanotubes
Flexible pressure sensor
High sensitivity
Porous electrode
Ultrathin dielectric layer
Carbon nanotubes
Flexible pressure sensor
Porous electrode
Ultrathin dielectric layer
High sensitivity
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Summary:Flexible capacitive pressure sensors have aroused widespread concern due to their promising application in wearable electronics. However, the trade-off between sensitivity and response range is yet to be resolved. Herein, flexible capacitive pressure sensors are developed based on high concentration carbon nanotube(CNT)-doped porous electrode and an ultrathin porous polyvinylidene difluoride (PVDF) dielectric layer. Benefit from the continuous variations of contacting area between the porous electrode and dielectric layer, as well as the larger relative distance, the sensor shows high sensitivity over a wide range (1.033 kPa−1 within 0–1 kPa, 0.72 kPa−1 within 1–5 kPa, 0.34 kPa−1 within 5–10 kPa and 0.23 kPa−1 within 10–30 kPa). The sensor is differentiated from other conventional capacitive pressure sensor, which usually relies on air gap or dielectric constants to tune sensor’s performance. The effect of CNT doping ratio, the thickness of dielectric layer and the thickness of porous electrode on the capacitance performance are explored. Fundamental understanding of the sensing mechanism is achieved through finite-element analysis and simplified analytical models. The capacitive sensor demonstrates its application in monitoring physiological signals such as the artery pulse, and muscle activation, showing potential in wearable healthcare monitor. [Display omitted] •High concentration CNT-doped porous electrode was developed.•An ultrathin dielectric layer made of porous PVDF fiber film was developed.•The sensitivity of the PCS sensor is up to 1.033 kPa−1 within 0–30 kPa.•The electrode has controllable deformation behavior.•The influence of the mechanical deformation behavior of the porous electrode on the capacitive performance is clarified.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2022.167919