3D Dielectric Layer Enabled Highly Sensitive Capacitive Pressure Sensors for Wearable Electronics

Zhao, Shufang; Ran, Wenhao; Wang, Depeng; Yin, Ranyu; Yan, Yunwei; Jiang, Kai; Lou, Zheng; Shen, Guozhen

doi:10.1021/acsami.0c09893

Cited by 104 publications

(80 citation statements)

References 35 publications

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“…[36] By adding a small microstructure in the PDMS dielectric layer, the pressure sensitivity was increased by more than 30 times compared with an unstructured PDMS layer of the same size. There are two main reasons for the significant increase in sensitivity: i) the presence of many voids in the microstructure film is conducive to a smaller elastic modulus and can provide a larger deformation space under the applied pressure, which means that the distance between two electrodes can change more to further increase ΔC under the same pressure; [36,41,78,94,95] ii) the dielectric constant of the polymer matrix (e.g., k PDMS ≈ 3.0) is higher than that of air (≈1). [36,62] When compression occurs, the air volume is occupied by the matrix, and ΔC increases accordingly.…”

Section: Bendable Pressure Sensorsmentioning

confidence: 99%

Flexible and Stretchable Capacitive Sensors with Different Microstructures

et al. 2021

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Recently, sensors that can imitate human skin have received extensive attention. Capacitive sensors have a simple structure, low loss, no temperature drift, and other excellent properties, and can be applied in the fields of robotics, human-machine interactions, medical care, and health monitoring. Polymer matrices are commonly employed in flexible capacitive sensors because of their high flexibility. However, their volume is almost unchanged when pressure is applied, and they are inherently viscoelastic. These shortcomings severely lead to high hysteresis and limit the improvement in sensitivity. Therefore, considerable efforts have been applied to improve the sensing performance by designing different microstructures of materials. Herein, two types of sensors based on the applied forces are discussed, including pressure sensors and strain sensors. Currently, five types of microstructures are commonly used in pressure sensors, while four are used in strain sensors. The advantages, disadvantages, and practical values of the different structures are systematically elaborated. Finally, future perspectives of microstructures for capacitive sensors are discussed, with the aim of providing a guide for designing advanced flexible and stretchable capacitive sensors via ingenious human-made microstructures.

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Section: Bendable Pressure Sensorsmentioning

confidence: 99%

Flexible and Stretchable Capacitive Sensors with Different Microstructures

et al. 2021

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“…To date, researchers have made lots of efforts to improve the comprehensive performance of the capacitive sensor in various aspects, such as sensitivity, detection limit/range, response time, and stability 12,[22][23][24] . For example, introducing the microstructure has been regarded as one of the effective strategies for remarkably improving the sensor sensitivity due to the distinct deformation of the microstructure and the subsequent increase in the capacitance variation.…”

Section: Introductionmentioning

confidence: 99%

Microstructured capacitive sensor with broad detection range and long-term stability for human activity detection

Liu

Shen

et al. 2021

npj Flex Electron

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In recent years, flexible stress sensors capable of monitoring diverse body movements and physiological signals have been attracting great attention in the fields of healthcare systems, human–machine interfaces, and wearable electronics. Inspired by the structure of natural eggshell inner membrane (ESIM), we developed a pressure sensor based on MXene (Ti3C2Tx)/Ag NWs (silver nanowires) composite electrodes and the micro-structured dielectric layer to meet the application requirements of wide detection range and long-term stability for the sensors. In the light of the nanoscale-microarray of the dielectric layer and the rough surface of electrode materials, this pressure sensor is expected to allow great and persistent deformation during the loading process. As a result, the device is characterized by an improved sensitivity, fast response (in the millisecond range), wide detection range (0–600 kPa), and long-term stability. The outstanding performance of the proposed sensor makes it possible to detect various human activities, such as speaking, air blowing, clenching, walking, finger/knee/elbow bending, and striking, demonstrating its good application prospects in wearable and flexible electronic devices.

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“…[1][2][3][4][5][6][7][8][9] Capacitive pressure sensors (CPSs), which are generally considered as a parallel plate capacitor consisting of a top/bottom electrode and a dielectric layer, have become an attractive type of FWS due to their advantages of simple structure fabrication, low power consumption, negligible temperature uctuation, fast response, and excellent stability. [10][11][12][13][14] However, the low sensitivity and narrow detection range are still limiting the overall performance and further applications of CPSs. [15][16][17] The sensing function of the capacitive sensor in response to the external stimuli is realized by monitoring the capacitance changes.…”

Section: Introductionmentioning

confidence: 99%