Development of triboelectric nanogenerator and mechanical energy harvesting using argon ion-implanted kapton, zinc oxide and kapton

Sahu, Manisha; Šafranko, Silvija; Hajra, Sugato; Padhan, Aneeta Manjari; Živković, Pavo; Jokić, Stela; Kim, Hoe Joon

doi:10.1016/j.matlet.2021.130290

Cited by 44 publications

(16 citation statements)

References 14 publications

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“…The electrification properties of other ion irradiated polymers, such as PET, PTFE, and FEP, are also systematically studied (Figure 7f), which suggests that the same ion irradiation can lead to different performance changes for different polymers. Argon ion implantation is carried out on Kapton to make it serve as a positive triboelectric layer, while pure Kapton behaves as a negative triboelectric layer [108]. The effect of argon plasma treatment (including plasma power and treatment time) on the output performance of TENG is also investigated [109].…”

Section: Ion Injection/irradiation/implantation/decorationmentioning

confidence: 99%

Smart Textile Triboelectric Nanogenerators: Prospective Strategies for Improving Electricity Output Performance

Dong

Xiao

Cheng

et al. 2022

Nanoenergy Advances

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By seamlessly integrating the wearing comfortability of textiles with the biomechanical energy harvesting function of a triboelectric nanogenerator (TENG), an emerging and advanced intelligent textile, i.e., smart textile TENG, is developed with remarkable abilities of autonomous power supply and self-powered sensing, which has great development prospects in the next-generation human-oriented wearable electronics. However, due to inadequate interface contact, insufficient electrification of materials, unavoidable air breakdown effect, output capacitance feature, and special textile structure, there are still several bottlenecks in the road towards the practical application of textile TENGs, including low output, high impedance, low integration, poor working durability, and so on. In this review, on the basis of mastering the existing theory of electricity generation mechanism of TENGs, some prospective strategies for improving the mechanical-to-electrical conversion performance of textile TENGs are systematically summarized and comprehensively discussed, including surface/interface physical treatments, atomic-scale chemical modification, structural optimization design, work environmental control, and integrated energy management. The advantages and disadvantages of each approach in output enhancement are further compared at the end of this review. It is hoped that this review can not only provide useful guidance for the research of textile TENGs to select optimization methods but also accelerate their large-scale practical process.

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Section: Ion Injection/irradiation/implantation/decorationmentioning

confidence: 99%

Smart Textile Triboelectric Nanogenerators: Prospective Strategies for Improving Electricity Output Performance

Dong

Xiao

Cheng

et al. 2022

Nanoenergy Advances

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“…As TENGs can operate in different working modes such as the CS mode, single-electrode mode, sliding mode, and free-standing mode, their manufacturing could be largely scalable and rapid production with low-cost materials . TENGs can be utilized as the power source of sensors for a diversity of applications, including biomedical purposes, environmental investigations, and human-machine interface organization. − Therefore, a promising route in achieving the battery-free sensor is coupling it with the TENG …”

Section: Introductionmentioning

confidence: 99%

Self-Powered Humidity Sensors Based on SnS₂ Nanosheets

Shooshtari

Rafiefard

Barzegar

et al. 2022

ACS Appl. Nano Mater.

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With the advent of the Internet of Things (IoT), the development of self-powered sensors has received much attention. Introducing triboelectric nanogenerators (TENGs) as a power source that converts mechanical movement into electrical signals has been admired recently. Moreover, the monitoring of humidity has become enormously essential in several technological contexts from environment monitoring to biomedical applications, thus joining these two subjects provides a huge benefit in achieving self-powered humidity sensors. Here, in this research, facile, lowpriced and self-powered humidity sensors are fabricated utilizing transition-metal dichalcogenides (TMD) nanosheets. Semi-vertical SnS 2 nanosheets are synthesized through a modified chemical vapor deposition method at moderate heat treatment (500 °C) utilizing pristine sensor's substrate and sulfur element on a laser grooved fluorine tin-doped oxide (FTO)/glass. To achieve a selfpowered device, the integrated contact-separated (CS) TENG of FTO and Kapton/Al has been coupled with the projected humidity sensor, through the impedance matching circuit. This self-powered SnS 2 humidity sensor demonstrated an outstanding response of about 400%, fast response and recovery times (∼4, and 7 s), and long-term stability (at least 5 months). Furthermore, the humidity effect on the electrical performance of the SnS 2 layer was studied through first-principle simulations. Based on calculated adsorption energies, charge transfer, electronic band structures, and density of states, H 2 O molecules physisorbed on the SnS 2 nanosheet with a strong adsorption energy of −1.82 eV and 0.0208 e/molecule charges transferred from H 2 O molecules to the surface. Our density functional theory calculations shed light on the humidity sensing mechanism by illustrating that both Sn and Sulfur atoms could act as adsorption sites. The introduced battery-free and self-powered humidity sensors have great conceivable application in wearable/ portable electronics and also smart homes.

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“…20 In this context, nanostructured metal-oxides and their composites can find potential utilization for TENG device performance due to their good chemical stability, high conductivity, large surface area, extreme sensitivity to modification of the structures and compositions, easy fabrication, and multifunctional behaviors. 21,22 Some metal-oxide composites have been reported previously as successful triboelectric materials: (i) Ti 0.8 O 2 nanosheets/silver nanopowders co-filled BaTiO 3 /PDMS hybrid nanogenerator TENG-PENG, which was capable of generating 150 V output; 23 (ii) ZnO-Kapton-based TENG device, which exhibited 12 μA and 57 V output; 24 (iii) ZnO nanorod arrays/PDMS-based TENG, which provided 0.181 μA and 5.34 V output, 25 (iv) a composite of Al 2 O 3 -PDMS, which showed 1.77 μA and 34 V output; 26 and (v) a NiO–Ni–MgO nanocomposite based TENG with an output of 35 V and an electrical current of 130 nA. 27 Table S1† shows a comparison of the present work with a state-of-the-art metal-oxides-based friction layer for the fabrication of TENGs and their output performances.…”

Section: Introductionmentioning

confidence: 99%

NiO–Ti nanocomposites for contact electrification and energy harvesting: experimental and DFT+U studies

Padhan

Hajra

Kumar

et al. 2022

Sustainable Energy Fuels

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Development of triboelectric nanogenerator and mechanical energy harvesting using argon ion-implanted kapton, zinc oxide and kapton

Cited by 44 publications

References 14 publications

Smart Textile Triboelectric Nanogenerators: Prospective Strategies for Improving Electricity Output Performance

Smart Textile Triboelectric Nanogenerators: Prospective Strategies for Improving Electricity Output Performance

Self-Powered Humidity Sensors Based on SnS₂ Nanosheets

NiO–Ti nanocomposites for contact electrification and energy harvesting: experimental and DFT+U studies

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Development of triboelectric nanogenerator and mechanical energy harvesting using argon ion-implanted kapton, zinc oxide and kapton

Cited by 44 publications

References 14 publications

Smart Textile Triboelectric Nanogenerators: Prospective Strategies for Improving Electricity Output Performance

Smart Textile Triboelectric Nanogenerators: Prospective Strategies for Improving Electricity Output Performance

Self-Powered Humidity Sensors Based on SnS2 Nanosheets

NiO–Ti nanocomposites for contact electrification and energy harvesting: experimental and DFT+U studies

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Product

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Self-Powered Humidity Sensors Based on SnS₂ Nanosheets