Functionalized multi‐wall carbon nanotubes/silicone rubber composite as capacitive humidity sensor

Wang, Dayue; Huang, Ying; Cai, Wei; Tian, Mengkui; Liu, Ping; Zhang, Yugang

doi:10.1002/app.40342

Cited by 19 publications

(11 citation statements)

References 24 publications

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“…However, the aim of this work is to demonstrate the advantages of suspended nanotube networks, in terms of response time, hysteresis and sensitivity. Many functionalization schemes have been reported in the literature [ 19 , 31 , 32 ] and could be used to improve response time, while benefiting from the suspended structure. The recovery time can also be further improved by incorporating a micro-heater into the device to promote heating and therefore faster desorption.…”

Section: Resultsmentioning

confidence: 99%

Suspended Carbon Nanotubes for Humidity Sensing

Arunachalam

Gupta

Izquierdo

et al. 2018

Sensors

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A room temperature microfabrication technique using SU8, an epoxy-based highly functional photoresist as a sacrificial layer, is developed to obtain suspended aligned carbon nanotube beams. The humidity-sensing characteristics of aligned suspended single-walled carbon nanotube films are studied. A comparative study between suspended and non-suspended architectures is done by recording the resistance change in the nanotubes under humidity. For the tests, the humidity was varied from 15% to 98% RH. A comparative study between suspended and non-suspended devices shows that the response and recovery times of the suspended devices was found to be almost 3 times shorter than the non-suspended devices. The suspended devices also showed minimal hysteresis even after 10 humidity cycles, and also exhibit enhanced sensitivity. Repeatability tests were performed by subjecting the sensors to continuous humidification cycles. All tests reported here have been performed using pristine non-functionalized nanotubes.

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Section: Resultsmentioning

confidence: 99%

Suspended Carbon Nanotubes for Humidity Sensing

Arunachalam

Gupta

Izquierdo

et al. 2018

Sensors

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“…Specifically, conductive polymer composite-based humidity sensors with incorporated electrically conductive fillers in insulating polymer matrixes are attracting much attention owing to their excellent flexibility, low cost, and ease of processing [21] , [22] , [23] , [24] , [25] , [26] , [27] . A range of polymers, such as poly (ethylene terephthalate) [28] , [29] , poly (ethylene-co-vinyl acetate) [30] , polyimide [31] , [32] , [33] , poly (ethyleneimine) [34] , poly (vinylidene fluoride) [35] , and silicone rubber [36] , have been demonstrated as platforms for the preparation of flexible humidity sensors. However, these petroleum-based polymers are nonbiodegradable that inevitably pose negative impacts on the environment.…”

Section: Introductionmentioning

confidence: 99%

Electrostatic self-assembly enabled flexible paper-based humidity sensor with high sensitivity and superior durability

Zhu

Kuang

Yuan

et al. 2021

Chemical Engineering Journal

139

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“…Conventional flexible capacitive sensors consist of a parallel‐plate capacitor, which comprises two conformable electrodes with a dielectric layer in‐between, [ 62–64 ] as presented in Figure . Stretchable dielectric materials are commonly used as flexible supports for soft strain sensors, such as rubbers (e.g., natural rubber and thermoplastic elastomers (TPEs)) [ 65–71 ] and silicone‐based elastomers (e.g., Ecoflex, Dragon Skin, and polydimethylsiloxane (PDMS)). [ 72–80 ] A huge difference in Young modulus between the thin metallic film (gold, aluminum, and platinum) and flexible elastomer or rubber causes cracks and buckling under stretching.…”

Section: Mechanisms and Sensitivitymentioning

confidence: 99%

Strain Sensing by Electrical Capacitive Variation: From Stretchable Materials to Electronic Interfaces

Nesser

Lubineau

2021

Adv Elect Materials

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Sensing the motion of objects and humans is essential for various applications, including human‐machine interfaces. Over the past few years, motion sensing has been extensively studied using capacitive strain sensors that can be utilized for wireless communications. The performance and functionality of capacitive strain sensors have been improved by achieving high sensitivity, large‐area sensing, ultra‐stretchability, and simplicity in design, measurement methods, and wireless integration. This review article highlights recent developments in capacitive strain sensors, including their characteristics and applications. First, the mechanisms and techniques employed to enhance the sensitivity of capacitive strain sensors are reviewed. Then, the notable features of this sensing strategy are highlighted, such as its ability to cover a wide area, properties of the required electronic interface, and sensor implementation inside a remote measurement system via an oscillating circuit. Therefore, a global review of the capacitive strain sensor that has been previously attempted can participate in developing an effective sensing method to meet the market need.

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Functionalized multi‐wall carbon nanotubes/silicone rubber composite as capacitive humidity sensor

Cited by 19 publications

References 24 publications

Suspended Carbon Nanotubes for Humidity Sensing

Suspended Carbon Nanotubes for Humidity Sensing

Electrostatic self-assembly enabled flexible paper-based humidity sensor with high sensitivity and superior durability

Strain Sensing by Electrical Capacitive Variation: From Stretchable Materials to Electronic Interfaces

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