A Wide‐Range Linear and Stable Piezoresistive Sensor Based on Methylcellulose‐Reinforced, Lamellar, and Wrinkled Graphene Aerogels

Li, Guochen; Chu, Zengyong; Gong, Xiaofeng; Xiao, Min; Dong, Qichao; Zhao, Zhenkai; Hu, Tianjiao; Zhang, Ye; Wang, Jing; Tan, Yinlong; Jiang, Zhenhua

doi:10.1002/admt.202101021

Cited by 15 publications

(10 citation statements)

References 56 publications

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“…In addition, a comparison of the sensing performance in terms of linearity, sensitivity, and linear range between the RLS sensor and other previously reported highly linear pressure sensors was conducted, as shown in Figure S23 and Table S1. Our sensor has achieved outstanding performance in ultra-broad linear pressure sensing, which, to the best of our knowledge, has not been previously reported and has been challenged. ,,,,,− Furthermore, a comparison with other 3D printed flexible porous sensors was conducted and listed in Table S2, demonstrating its distinguishable characters with broad linear range, compact size, and without 3D model design. − ,− …”

Section: Resultsmentioning

confidence: 86%

Ultra-Broad Linear Range and Sensitive Flexible Piezoresistive Sensor Using Reversed Lattice Structure for Wearable Electronics

Bang

Chun

Lim

et al. 2023

ACS Appl. Mater. Interfaces

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Flexible pressure sensors have attracted significant attention owing to their broad applicability in wearable electronics and human–machine interfaces. However, it is still challenging to simultaneously achieve a broad sensing range and high linearity. Here, we present a reversed lattice structure (RLS) piezoresistive sensor obtained through a layer-level engineered additive infill structure via conventional fused deposition modeling three-dimensional (3D) printing. The optimized RLS piezoresistive sensor attained a pressure sensing range (0.03–1630 kPa) with high linearity (coefficient of determination, R 2 = 0.998) and sensitivity (1.26 kPa–1) due to the structurally enhanced compressibility and spontaneous transition of dominant sensing mechanism of the sensor. It also exhibited great mechanical/electrical durability and a rapid response/recovery time (170/70 ms). This remarkable performance enables the detection of various human motions over a broad spectrum, from pulse detection to human walking. Finally, a wearable electronic glove was developed to analyze the pressure distribution in various situations, thereby demonstrating its applicability in multipurpose wearable electronics.

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Section: Resultsmentioning

confidence: 86%

Ultra-Broad Linear Range and Sensitive Flexible Piezoresistive Sensor Using Reversed Lattice Structure for Wearable Electronics

Bang

Chun

Lim

et al. 2023

ACS Appl. Mater. Interfaces

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show abstract

“…Among them, flexible piezoresistive sensors can be manufactured in various modes through different combinations of elastic substrate materials and micro-nano conductive media, which have the advantages of a simple structure, easy manufacturing process, low cost, high sensitivity and a wide response range. The resistive sensors with flexible substrates such as silicone, PDMS, and gel are closer to the mechanical properties of human skin by virtue of their flexibility and high ductility [ 9 , 10 , 11 ].…”

Section: Introductionmentioning

confidence: 99%

Strain and Pressure Sensors Based on MWCNT/PDMS for Human Motion/Perception Detection

et al. 2023

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Flexible wearable devices have attracted wide attention in capacious fields because of their real-time and continuous monitoring of human information. The development of flexible sensors and corresponding integration with wearable devices is of great significance to build smart wearable devices. In this work, multi-walled carbon nanotube/polydimethylsiloxane-based (MWCNT/PDMS) resistive strain sensors and pressure sensors were developed to integrate a smart glove for human motion/perception detection. Firstly, MWCNT/PDMS conductive layers with excellent electrical and mechanical properties (resistivity of 2.897 KΩ · cm, elongation at break of 145%) were fabricated via a facile scraping-coating method. Then, a resistive strain sensor with a stable homogeneous structure was developed due to the similar physicochemical properties of the PDMS encapsulation layer and MWCNT/PDMS sensing layer. The resistance changes of the prepared strain sensor exhibited a great linear relationship with the strain. Moreover, it could output obvious repeatable dynamic response signals. It still had good cyclic stability and durability after 180° bending/restoring cycles and 40% stretching/releasing cycles. Secondly, MWCNT/PDMS layers with bioinspired spinous microstructures were formed by a simple sandpaper retransfer process and then assembled face-to-face into a resistive pressure sensor. The pressure sensor presented a linear relationship of relative resistance change and pressure in the range of 0–31.83 KPa with a sensitivity of 0.026 KPa−1, and a sensitivity of 2.769 × 10−4 KPa−1 over 32 KPa. Furthermore, it responded quickly and kept good cycle stability at 25.78 KPa dynamic loop over 2000 s. Finally, as parts of a wearable device, resistive strain sensors and a pressure sensor were then integrated into different areas of the glove. The cost-effective, multi-functional smart glove can recognize finger bending, gestures, and external mechanical stimuli, which holds great potential in the fields of medical healthcare, human-computer cooperation, and so on.

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“…Li et al utilized methylcellulose-reinforced, lamellar, and wrinkled graphene aerogels to prepare a sensor with high linearity over a wide range. 37 Jia et al employed an rGO film with a wrinkled structure as a sensitive layer for subtle mechanical sensing. 38 Hu et al developed a graphene-based e-textile to realize the perception of physiological signals.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Currently, various mechanical sensors are being explored for subtle mechanical force monitoring. Li et al utilized methylcellulose-reinforced, lamellar, and wrinkled graphene aerogels to prepare a sensor with high linearity over a wide range . Jia et al employed an rGO film with a wrinkled structure as a sensitive layer for subtle mechanical sensing .…”

Section: Introductionmentioning

confidence: 99%

Graphene-based Two-Stage Enhancement Pressure Sensor for Subtle Mechanical Force Monitoring

Tian,

Li,

Gou

et al. 2023

ACS Appl. Mater. Interfaces

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The development of pressure sensors with high sensitivity and a low detection limit for subtle mechanical force monitoring and the understanding of the sensing mechanism behind subtle mechanical force monitoring are of great significance for intelligent technology. Here, we proposed a graphene-based two-stage enhancement pressure sensor (GTEPS), and we analyzed the difference between subtle mechanical force monitoring and conventional mechanical force monitoring. The GTEPS exhibited a high sensitivity of 62.2 kPa −1 and a low detection limit of 0.1 Pa. Leveraging its excellent performance, the GTEPS was successfully applied in various subtle mechanical force monitoring applications, including acoustic wave detection, voice-print recognition, and pulse wave monitoring. In acoustic wave detection, the GTEPS achieved a 100% recognition accuracy for six words. In voiceprint recognition, the sensor exhibited accurate identification of distinct voiceprints among individuals. Furthermore, in pulse wave monitoring, GTEPS demonstrated effective detection of pulse waves. By combination of the pulse wave signals with electrocardiogram (ECG) signals, it enabled the assessment of blood pressure. These results demonstrate the excellent performance of GTEPS and highlight its great potential for subtle mechanical force monitoring and its various applications. The current results indicate that GTEPS shows great potential for applications in subtle mechanical force monitoring.

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A Wide‐Range Linear and Stable Piezoresistive Sensor Based on Methylcellulose‐Reinforced, Lamellar, and Wrinkled Graphene Aerogels

Cited by 15 publications

References 56 publications

Ultra-Broad Linear Range and Sensitive Flexible Piezoresistive Sensor Using Reversed Lattice Structure for Wearable Electronics

Ultra-Broad Linear Range and Sensitive Flexible Piezoresistive Sensor Using Reversed Lattice Structure for Wearable Electronics

Strain and Pressure Sensors Based on MWCNT/PDMS for Human Motion/Perception Detection

Graphene-based Two-Stage Enhancement Pressure Sensor for Subtle Mechanical Force Monitoring

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