Development of a piezoelectric nanogenerator based on mesoporous silica/zinc oxide hybrid nanocomposite fibres

Bhadra, Jolly; Ponnamma, Deepalekshmi; Alkareem, Asma; Parangusan, Hemalatha; Ahmad, Zubair; Al‐Thani, Noora; Daifalla, Amal K. E.; Al‐Sanari, Noora Ali; Mohamed, Radwa

doi:10.1002/er.7734

Cited by 2 publications

(2 citation statements)

References 37 publications

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“…PiENG is a kind of device that converts external mechanical energy into electrical energy by using nano-scale piezoelectric body as an energy source. At present, there are several vibration energy acquisition technologies based on electromagnetic drive, electrostatic drive, and magneto strictive drive at home and abroad [37]. However, the existing energy acquisition technology is difficult to meet the needs of micro sensors, and the electromagnetic energy acquisition technology has some problems, such as the size of the magnet and coil being too large, the output voltage being too low, and it being easy to be affected by electromagnetic interference.…”

Section: Self-powered Sensormentioning

confidence: 99%

Advancements in Passive Wireless Sensors, Materials, Devices, and Applications

He,

Cui,

Ming

et al. 2023

Sensors

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In recent years, passive wireless sensors have been studied for various infrastructure sectors, making them a research and development focus. While substantial evidence already supports their viability, further effort is needed to understand their dependability and applicability. As a result, issues related to the theory and implementation of wireless sensors still need to be resolved. This paper aims to review and summarize the progress of the different materials used in different passive sensors, the current status of the passive wireless sensor readout devices, and the latest peripheral devices. It will also cover other related aspects such as the system equipment of passive wireless sensors and the nanogenerators for the energy harvesting for self-powered sensors for applications in contemporary life scenarios. At the same time, the challenges for future developments and applications of passive wireless are discussed.

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Section: Self-powered Sensormentioning

confidence: 99%

Advancements in Passive Wireless Sensors, Materials, Devices, and Applications

He,

Cui,

Ming

et al. 2023

Sensors

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“…In order to understand the mechanism of piezoelectricity in polymer nanocomposites and the various materials used for fabricating PENGs, the review of Mishra et al [ 19 ] is helpful. Our research group has done extensive research on the piezoelectric properties of polyvinylidene fluoride (PVDF) [ 20 , 21 ] and its copolymer, polyvinylidene fluoride hexafluoropropylene (PVDF-HFP) [ 22 , 23 ]. Depending on the synthesis method and the nature of the nanofillers used, the piezoelectric nanocomposites showed different rates of performance.…”

Section: Introduction and Background Surveymentioning

confidence: 99%

Influence of phase-separated structural morphologies on the piezo and triboelectric properties of polymer composites

Yempally,

Kacem,

Ponnamma

2023

Discover Nano

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Simplified and flexible fabrication methods, high output performance, and extreme flexibility of polymer-based nanocomposites represent versatile designs in self-powering devices for wearable electronics, sensors, and smart societies. Examples include polyvinylidene fluoride and its copolymers-based piezoelectric nanogenerators, green and recyclable triboelectric nanogenerators, etc. Advanced functionalities, multi-functional properties, and the extensive lifetime required for nanogenerators inspire researchers to focus on structural modifications of the polymeric materials, to fully exploit their performances. Phase separation is a physicochemical process in which polymeric phases rearrange, resulting in specific structures and properties, that ultimately influence mechanical, electronic, and other functional properties. This article will study the phase separation strategies used to modify the polymeric base, both physically and chemically, to generate the maximum electric power upon mechanical and frictional deformation. The effect of interfacial modification on the efficiency of the nanogenerators, chemical and mechanical stability, structural integrity, durable performance, and morphological appearance will be extensively covered in this review. Moreover, piezo- and triboelectric power generation have numerous challenges, such as poor resistance to mechanical deformation, reduced cyclic performance stability, and a high cost of production. These often depend on the method of developing the nanogenerators, and phase separation provides a unique advantage in reducing them. The current review provides a one-stop solution to understand and disseminate the phase separation process, types and mechanisms, advantages, and role in improving the piezoelectric and triboelectric performances of the nanogenerators.

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Development of a piezoelectric nanogenerator based on mesoporous silica/zinc oxide hybrid nanocomposite fibres

Cited by 2 publications

References 37 publications

Advancements in Passive Wireless Sensors, Materials, Devices, and Applications

Advancements in Passive Wireless Sensors, Materials, Devices, and Applications

Influence of phase-separated structural morphologies on the piezo and triboelectric properties of polymer composites

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