A critical review on lead-free hybrid materials for next generation piezoelectric energy harvesting and conversion

Banerjee, Swagata; Bairagi, Satyaranjan; Ali, S. Wazed

doi:10.1016/j.ceramint.2021.03.054

Cited by 64 publications

(31 citation statements)

References 145 publications

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“…This review complements other published reviews on the topic 21,[26][27][28][29] by providing a careful examination of literature to gain a better grasp of the underlying mechanism of piezoelectricity with a particular focus on biological materials. It also attempts to provide a summary of key piezoelectric biological and traditional materials, their differences, applications and limitations, as well as a brief overview of the current state of piezoelectric development.…”

Section: Introductionmentioning

confidence: 84%

The intrinsic piezoelectric properties of materials – a review with a focus on biological materials

2021

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Section: Introductionmentioning

confidence: 84%

The intrinsic piezoelectric properties of materials – a review with a focus on biological materials

2021

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Section: Piezoelectric Energy Harvestingmentioning

confidence: 99%

“…The piezoelectric response reached a peak-to-peak voltage of 840 mV under a 1N applied force. Efforts have also been made to develop lead-free alternative piezoceramic fillers for more health-and environmentally friendly strategies [82]. In addition to PVDF-based composite and nanocomposite, other materials have been investigated for textile applications.…”

Section: Composites/nanocompositesmentioning

confidence: 99%

Energy Harvesting Materials and Structures for Smart Textile Applications: Recent Progress and Path Forward

Dolez

2021

Sensors

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A major challenge with current wearable electronics and e-textiles, including sensors, is power supply. As an alternative to batteries, energy can be harvested from various sources using garments or other textile products as a substrate. Four different energy-harvesting mechanisms relevant to smart textiles are described in this review. Photovoltaic energy harvesting technologies relevant to textile applications include the use of high efficiency flexible inorganic films, printable organic films, dye-sensitized solar cells, and photovoltaic fibers and filaments. In terms of piezoelectric systems, this article covers polymers, composites/nanocomposites, and piezoelectric nanogenerators. The latest developments for textile triboelectric energy harvesting comprise films/coatings, fibers/textiles, and triboelectric nanogenerators. Finally, thermoelectric energy harvesting applied to textiles can rely on inorganic and organic thermoelectric modules. The article ends with perspectives on the current challenges and possible strategies for further progress.

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“…As an aim to facilitate the natural and causal interaction between such devices and humans, the embedding of ubiquitous computation into environments has drawn significant research attention along with the concepts of sensation and perception. Examples of such systems are WSNs, which show potential applicability in many areas [7][8][9]: piezoelectric conversion technology [10][11][12], solar system [13], thermoelectricpowered [14], and wind power systems [15,16]. These systems are capable of harvesting energy from ambient environments, which activate devices directly and finally store harvested energy in infinite capacity batteries for future use [17].…”

Section: Introductionmentioning

confidence: 99%

Review of Power Converter Impact of Electromagnetic Energy Harvesting Circuits and Devices for Autonomous Sensor Applications

et al. 2021

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The demand for power is increasing due to the rapid growth of the population. Therefore, energy harvesting (EH) from ambient sources has become popular. The reduction of power consumption in modern wireless systems provides a basis for the replacement of batteries with the electromagnetic energy harvesting (EMEH) approach. This study presents a general review of the EMEH techniques for autonomous sensor (ATS) applications. Electromagnetic devices show great potential when used to power such ATS technologies or convert mechanical energy to electrical energy. As its power source, this stage harvests ambient energy and features a self-starting and self-powered process without the use of batteries. Therefore, it consumes low power and is highly stable for harvesting energy from the environment with low ambient energy sources. The review highlights EMEH circuits, low power EMEH devices, power electronic converters, and controllers utilized in numerous applications, and described their impacts on energy conservation, benefits, and limitation. This study ultimately aims to suggest a smart, low-voltage electronic circuit for a low-power sensor that harvests electromagnetic energy. This review also focuses on various issues and suggestions of future EMEH for low power autonomous sensors.

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A critical review on lead-free hybrid materials for next generation piezoelectric energy harvesting and conversion

Cited by 64 publications

References 145 publications

The intrinsic piezoelectric properties of materials – a review with a focus on biological materials

The intrinsic piezoelectric properties of materials – a review with a focus on biological materials

Energy Harvesting Materials and Structures for Smart Textile Applications: Recent Progress and Path Forward

Review of Power Converter Impact of Electromagnetic Energy Harvesting Circuits and Devices for Autonomous Sensor Applications

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