A Flexible Temperature Sensor Based on Reduced Graphene Oxide for Robot Skin Used in Internet of Things

Liu, Guanyu; Tan, Qiulin; Kou, Hairong; Zhang, Lei; Wang, Jinqi; Lv, Wen; Dong, Helei; Xiong, Jijun

doi:10.3390/s18051400

Cited by 211 publications

(137 citation statements)

References 30 publications

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“…Nevertheless, these techniques require specialised equipment and are not easily scaled up to large area fabrication. Solution based processes such as spin coating [193], spray coating [337], electrospinning [147], roll-to-roll printing [338], inkjet printing [137,339,340], dispenser printing [341], and screen printing [337,342], offer an easier approach for the deposition of films on large area flexible substrates. In addition, these techniques are mostly applied at low temperatures, making them compatible with substrates that require a low thermal budget.…”

Section: Fabrication Methodsmentioning

confidence: 99%

“…Electrical contact sensors change their electrical properties with respect to temperature. Most of the flexible temperature sensors fall into the electrical contact sensors category and they are either resistive [103,337,339,341,342,344,345,349,[437][438][439][440][441][442][443][444][445][446][447][448][449][450][451], pyroelectric [296,375,[452][453][454][455][456][457], capacitive [145,[458][459][460], thermoelectric [145,458,459], transistors [11,460], or diodes [441]. The performance of a temperature sensor is generally assessed by investigating its temperature sensitivity, temperature range, hysteresis and response time.…”

Section: Temperature Sensorsmentioning

confidence: 99%

“…The resistance is then used to estimate the temperature of the metal. The sensitivity is often described using the sensors temperature coefficient of the resistance (TCR) [337].…”

Section: Resistance Temperature Detectorsmentioning

confidence: 99%

“…In a NTC thermistor the resistance decreases with the increase in temperature, and the opposite occurs in the case of a PTC thermistor [461]. Thermistors were manufactured using graphene [337,448], CNTs [337,447], graphite [103,341], PEDOT:PSS [462], polyaniline nanofibre [451], polycarbonate/α -(BEDT -TTF)2I x Br 3-x [449], and hydrogels [450].…”

Section: Thermistormentioning

confidence: 99%

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Flexible Sensors—From Materials to Applications

et al. 2019

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Flexible sensors have the potential to be seamlessly applied to soft and irregularly shaped surfaces such as the human skin or textile fabrics. This benefits conformability dependant applications including smart tattoos, artificial skins and soft robotics. Consequently, materials and structures for innovative flexible sensors, as well as their integration into systems, continue to be in the spotlight of research. This review outlines the current state of flexible sensor technologies and the impact of material developments on this field. Special attention is given to strain, temperature, chemical, light and electropotential sensors, as well as their respective applications.

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Section: Fabrication Methodsmentioning

confidence: 99%

Section: Temperature Sensorsmentioning

confidence: 99%

“…The resistance is then used to estimate the temperature of the metal. The sensitivity is often described using the sensors temperature coefficient of the resistance (TCR) [337].…”

Section: Resistance Temperature Detectorsmentioning

confidence: 99%

Section: Thermistormentioning

confidence: 99%

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Flexible Sensors—From Materials to Applications

et al. 2019

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“…A great number of wearable and flexible sensors have been developed for various functions in recent years, such as temperature sensor, humidity sensor, strain sensor, and pH sensor. [ 1–6 ] Among these sensors, flexible strain sensors, which transduce mechanical stimuli into electrical counterparts, have been the major interest of many research teams because of the ubiquitous mechanical energy in the surroundings from human body motions even to air flow. [ 7–9 ] On the basis of different mechanisms, flexible strain sensors can be divided into several types including piezoresistivity, capacity, and piezoelectricity.…”

Section: Introductionmentioning

confidence: 99%

Wearable and Ultrasensitive Strain Sensor Based on High‐Quality GaN pn Junction Microwire Arrays

Cheng

Han

Cao

et al. 2020

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With the rapid growth in wearable electronics sensing devices, flexible sensing devices that monitor the human body have shown great promise in personalized healthcare. In the study, high-quality GaN pn junction microwire arrays with different aspect ratios and large-area uniformity are fabricated through an easy, repeatable fabrication process. The piezoelectric coefficient (d 33 ) of GaN pn junction microwire arrays increases from 7.23 to 14.46 pm V −1 with the increasing of the aspect ratio, which is several times higher than that of GaN bulk material. Furthermore, flexible ultrasensitive strain sensor based on GaN microwires with the highest d 33 is demonstrated to achieve the maximum open circuit voltage of 10.4 V, and presents excellent durability with stable output signals over 10 000 cycles with a response time of 50 ms. As a flexible and wearable sensor attached to the human skin, the GaN microwire pn junction arrays with such a high degree of uniformity can precisely monitor subtle human pulse and motions, which show great promise in future personalized healthcare.The piezoresistive strain sensors are unquestionably promising candidates for wearable and real-time human motiondetecting devices, [15,16] and they can be sensitive enough for even 10 nm vibration, [17] but the piezoelectric sensors are more prospective for self-powered devices owing to the piezoelectric effect of materials, defined as the occurrence of polarization when the material is subjected to external stress as a result of the separation of the positive and negative gravity centers of the molecules. Lead zirconate titanate (PZT) and polyvinylidene fluoride (PVDF) are the most commonly used piezoelectric mediums for piezoelectric sensors due to their high piezoelectric coefficients (d 33 ). [18][19][20][21] However, the toxic lead component in PZT and the high impedance of PVDF have limited their applications in wearable piezoelectric devices. [22,23] In this regard, semiconductor-based piezoelectric strain sensors represented by zinc oxide (ZnO) and GaN have been extensively studied as a result of their mechanical and chemical stability as well as environmental and biological compatibility. [24][25][26][27][28] In addition to the above advantages of the semiconductor, GaN exhibits merits of easy control of carrier concentration doping and higher stability compared to ZnO, while internal free carriers reduce the output of the device by screening the piezoelectric polarization, which is called free carriers screening. Suppressing the free carriers screening is undoubtedly an effective approach to improve the piezoelectric performance of the devices. [27,29,30] Another method is replacing the bulk or film materials with nanowires (NWs) considering the superior mechanical properties, large aspect ratio, and high energy conversion efficiency of NWs as compared to bulk materials. [31][32][33][34][35] For instance, Kacimi et al. fabricated a flexible strain sensor exhibiting 2 V peak outputs with vertically aligned ultra-long GaN wires, [36] ...

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Electrospun Nanofibers for Flexible Sensors

Wang,

Zhang

2024

Electrospinning

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A Flexible Temperature Sensor Based on Reduced Graphene Oxide for Robot Skin Used in Internet of Things

Cited by 211 publications

References 30 publications

Flexible Sensors—From Materials to Applications

Flexible Sensors—From Materials to Applications

Wearable and Ultrasensitive Strain Sensor Based on High‐Quality GaN pn Junction Microwire Arrays

Electrospun Nanofibers for Flexible Sensors

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