PDMS-based Triboelectric and Transparent Nanogenerators with ZnO Nanorod Arrays

Ko, Yeong Hwan; Nagaraju, Goli; Lee, Soo Hyun; Yu, Jae Su

doi:10.1021/am5018072

Cited by 175 publications

(133 citation statements)

References 25 publications

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“…It is evident that the average voltage and current (solid parts of peaks in each figure) gradually increase with the increase of frequency, while the maximum upper peak voltage remains almost same at around 20 V. The increase in average voltage and current is attributed to the increase in the average surface charge as the bending frequency is increased. This occurs due to the slower discharge rate of the device as compared to the input pulse rate, resulting in a continuous rise in the output voltage and current as frequency is increased [29,30]. At 30 Hz, the peak value of average voltage and current is 5.8 V and 3.2 µA (see Table 2), while the maximum upper peak value of voltage and current is 20 V and 6.5 µA.…”

Section: Resultsmentioning

confidence: 99%

P(VDF-TrFE) Film on PDMS Substrate for Energy Harvesting Applications

et al. 2018

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Abstract:We have developed and demonstrated a highly flexible P(VDF-TrFE) film-based energy harvesting device on a PDMS substrate, avoiding any complex composites and patterned structures. The structural and electrical properties of the P(VDF-TrFE) film was investigated using multiple characterization techniques and an optimized film of 7 µm thickness was used for the energy harvesting application. The device, with Ti/Ni metal contacts, was driven by a shaker providing an acceleration of 1.75 g, and frequencies varying from 5 to 30 Hz. The energy harvesting performance of the final fabricated device was tested using the shaker, and resulted in a maximum output capacitor voltage of 4.4 V, which successfully powered a set of 27 LEDs after several minutes of charging.

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Section: Resultsmentioning

confidence: 99%

P(VDF-TrFE) Film on PDMS Substrate for Energy Harvesting Applications

et al. 2018

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“…The triboelectricity has recently been attracting a great deal of attention since it turned out to be a very promising concept in view of the energy harvesting. [18][19][20] In the energy harvesting device consisting of PDMS and ZnO, the repetitive pushing/separating operations generated positive/negative current signal. 18 PDMS was negatively charged relative to ZnO.…”

Section: -15mentioning

confidence: 99%

“…[18][19][20] In the energy harvesting device consisting of PDMS and ZnO, the repetitive pushing/separating operations generated positive/negative current signal. 18 PDMS was negatively charged relative to ZnO. Assuming ZnO and ZnS to be similar in terms of dielectric property, a certain amount of charge would be accumulated on the interface between the ZnS:Cu particle and the PDMS matrix during the elongation/retreat of the ZnS:Cu-PDMS composite.…”

Section: -15mentioning

confidence: 99%

Mechanically driven luminescence in a ZnS:Cu-PDMS composite

et al. 2016

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The conventional mechanoluminescence (ML) mechanism of phosphors such as SrAl2O4:Eu and ZnS:Mn is known to utilize carrier trapping at shallow traps followed by stress (or strain)-induced detrapping, which leads to activator recombination in association with local piezoelectric fields. However, such a conventional ML mechanism was found to be invalid for the ZnS:Cu-embedded polydimethylsiloxane (PDMS) composite, due to the absence of luminescence with a rigid matrix and a negligibly small value of the piezoelectric coefficient (d33) of the composite. An alternative mechanism, namely, the triboelectricity-induced luminescence has been proposed for the mechanically driven luminescence of a ZnS:Cu-PDMS composite.

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“…In addition, transparent TENGs using indium tin oxide (ITO) or graphene as electrodes have been achieved, which enable applications that require high transparency such as touch screens [31][32][33][34][35] . Our previous work shows that using C 4 F 8 to treat uncured PDMS could deposit fluorocarbon polymer and a wrinkle structure in single step [18][19][20] , which had the advantage of significantly increasing the performance of the flexible TENG.…”

Section: Introductionmentioning

confidence: 99%

“…Although using a flat surface could provide the highest transparency, the performance of the TENGs will be weakened to some degree 38 . Notably, previous work reported that a PDMS surface with nanopattern sizes o 310 nm could result in high transmittances (above 85%) owing to an effective graded refractive index profile 32,33 . Using a structure of several hundred nanometers provides us with an effective way to realize highperformance and highly transparent TENGs.…”

Section: Introductionmentioning

confidence: 99%

Controlled fabrication of nanoscale wrinkle structure by fluorocarbon plasma for highly transparent triboelectric nanogenerator

Cheng

Miao

et al. 2017

Microsyst Nanoeng

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In this paper, we report a novel nanoscale wrinkle-structure fabrication process using fluorocarbon plasma on poly (dimethylsiloxane) (PDMS) and Solaris membranes. Wrinkles with wavelengths of hundreds of nanometers were obtained on these two materials, showing that the fabrication process was universally applicable. By varying the plasma-treating time, the wavelength of the wrinkle structure could be controlled. Highly transparent membranes with wrinkle patterns were obtained when the plasmatreating time was o 125 s. The transmittances of these membranes were 490% in the visible region, making it difficult to distinguish them from a flat membrane. The deposited fluorocarbon polymer also dramatically reduced the surface energy, which allowed us to replicate the wrinkle pattern with high precision onto other membranes without any surfactant coating. The combined advantages of high electron affinity and high transparency enabled the fabricated membrane to improve the performance of a triboelectric nanogenerator. This nanoscale, single-step, and universal wrinkle-pattern fabrication process, with the functionality of high transparency and ultra-low surface energy, shows an attractive potential for future applications in microand nanodevices, especially in transparent energy harvesters. INTRODUCTIONPatterned surface structures on the nano-or micrometer scale have a significant role in the properties of a material, including physical, mechanical, electrical, and optical 1 . The fabrication process for these patterns has been traditionally realized by photolithography, printing processes, embossing, or writing techniques, of which the relatively high cost and low throughput limit their application for producing complex topologies over large areas. Thereby, selfassembled patterns for large-area patterning, which generally employ physical-chemical or mechanical instabilities within a constrained system to form highly ordered structures, have attracted great attention for many years 2-7 . Among these methods, mechanically inducing a wrinkle structure on a bilayer system is especially suited to creating highly ordered microstructures across a large surface and features convenient fabrication and a tunable wavelength by adjusting the thickness of the stiff layer and the prestrain [8][9][10][11][12] . As a result, wrinkle structures have been used in various applications, such as smart adhesion, liquid/cell shaping, particle assembly, optical surfaces, flexible electronic devices, and energy harvesters [13][14][15][16][17][18][19][20] . To date, most studies involving wrinkling to create ordered structures rely on plasma or ultraviolet-ozonolysis (UVO) oxidation and metal deposition to create the stiff skin. Although these approaches are quite practical, the material properties of the substrate during oxidation can significantly alter the typical morphologies and even block the formation of the wrinkle structure (that is, the process does not have universality to different materials), whereas the deposition of the metal la...

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PDMS-based Triboelectric and Transparent Nanogenerators with ZnO Nanorod Arrays

Cited by 175 publications

References 25 publications

P(VDF-TrFE) Film on PDMS Substrate for Energy Harvesting Applications

P(VDF-TrFE) Film on PDMS Substrate for Energy Harvesting Applications

Mechanically driven luminescence in a ZnS:Cu-PDMS composite

Controlled fabrication of nanoscale wrinkle structure by fluorocarbon plasma for highly transparent triboelectric nanogenerator

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