Fundamental study of mechanical energy harvesting using piezoelectric nanostructures

Sun, Chengliang; Shi, Jian; Wang, Xudong

doi:10.1063/1.3462468

Cited by 126 publications

(85 citation statements)

References 41 publications

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“…Recently, piezoelectric energy harvesting devices based on piezoelectric nanowires have attracted more attention due to their signicant electrical and mechanical properties at the nanoscale. 5 A range of piezoelectric nanostructure such as ZnO nanowires, BaTiO 3 nanobers, and PZT nanobers have been examined for energy harvesting applications. [6][7][8] In particular, piezoelectric exible nanostructures based energy harvester on single plastic substrate could be fabricated by using simple transfer process without employing complicated high temperature process.…”

Section: Introductionmentioning

confidence: 99%

Piezoelectric energy harvesting from a PMN–PT single nanowire

et al. 2017

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Flexible piezoelectric generators constructed using one-dimensional nanostructures are well known for their efficient energy harvesting. Herein, we have fabricated a flexible piezoelectric energy harvester (PEH) consisting of a single 0.65Pb(Mg 1/3 Nb 2/3 )O 3 -0.35PbTiO 3 nanowire (PMN-PT NW) using a facile transferring approach onto a Au electrode-patterned plastic substrate. The well-developed device effectively harvested the maximum output signals (9 mV and 1.5 nA) originating from a single PMN-PT nanowire under mechanical bending/unbending motions. The designed PEH is also expected to be utilized as a versatile tool to evaluate the performance of a one-dimensional nanostructure.

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Section: Introductionmentioning

confidence: 99%

Piezoelectric energy harvesting from a PMN–PT single nanowire

et al. 2017

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“…In recent years, ZnO NWs have garnered significant interest for sensing and energy harvesting; however, ZnO possess both a low piezoelectric coupling coefficient and semiconductor behaviour unlike many ferroelectric ceramics and, therefore, can result in sensors with low sensitivity and a high noise floor 15 . Although ZnO NWs have a low dielectric constant, which increases its voltage output, the performance has been very limited and no sensor has been demonstrated to produce a high coherence between the input and output across the sensor's bandwidth 5,[16][17][18] .…”

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confidence: 99%

High-sensitivity accelerometer composed of ultra-long vertically aligned barium titanate nanowire arrays

2013

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A configuration that shows great promise in sensing applications is vertically aligned piezoelectric nanowire arrays that allow facile interfacing with electrical interconnects. Nanoelectromechanical systems developed using piezoelectric nanowires have gained interest primarily for their potential in energy harvesting applications, because they are able to convert several different sources of mechanical energy into useful electrical power. To date, no results have demonstrated the capability to use aligned piezoelectric nanowire arrays as a highly accurate nano-electromechanical system based dynamic sensor with a wide operating bandwidth and unity coherence. Here we report the growth of vertically aligned (B45 mm long) barium titanate nanowire arrays, realized through a two-step hydrothermal synthesis approach, and demonstrate their use as an accurate accelerometer. High sensitivity of up to 50 mVg À 1 is observed from the sensor composed of vertically aligned barium titanate nanowire arrays, thus providing performance comparable to many of the commercial accelerometer systems.

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“…As observed from literature review [2,4,[27][28][29][30][31][32][33][34], nano-sized structures of piezoelectric materials like PZT, BaTiO3, ZnO, PVDF, InN, GaN, CdS etc. have been studied intensively as effective and efficient building blocks for converting ambient mechanical energy into electricity.…”

Section: Materials For Energy Harvesting Fabricsmentioning

confidence: 85%

A Review on Energy Harvesting Using 3D Printed Fabrics for Wearable Electronics

Gowthaman

Chidambaram

Rao

et al. 2016

J. Inst. Eng. India Ser. C

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Embedding of energy harvesting systems into wearable health and environment monitoring systems, like integration of smart piezoelectric fibers into soldier fabric structures opens up avenues in generating electricity from natural mechanical movements for selfpowering of wearable electronics. Emergence of multitudinous of materials and manufacturing technologies has enabled realization of various energy harvesting systems from mechanical movements. The materials and manufacturing related to 3D printing of energy harvesting fabrics are reviewed in this paper. State-of-the-art energy harvesting sources are briefly described following which an in-depth analysis on the materials and 3D printing techniques for energy harvesting fabrics are presented. While tremendous motivation and opportunity exists for wider-scale adoption of 3D printing for this niche area, the success depends on efficient design of three critical factors namely materials, process and structure. The present review discusses on the complex issues of materials selection, modelling and processing of 3D printed fabrics. The paper culminates by presenting a discussion on how future advancements in 3D printing technology might be useful for development of wearable electronics.

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Fundamental study of mechanical energy harvesting using piezoelectric nanostructures

Cited by 126 publications

References 41 publications

Piezoelectric energy harvesting from a PMN–PT single nanowire

Piezoelectric energy harvesting from a PMN–PT single nanowire

High-sensitivity accelerometer composed of ultra-long vertically aligned barium titanate nanowire arrays

A Review on Energy Harvesting Using 3D Printed Fabrics for Wearable Electronics

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