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Enhancement of piezoelectricity via electrostatic effects on a textile platform
- Enhancement of piezoelectricity via electrostatic effects on a textile platform
- Kim, H[Kim, Hyunjin]; Kim, SM[Kim, Seong Min]; Son, H[Son, Hyungbin]; Kim, H[Kim, Hyeok]; Park, B[Park, BoongIk]; Ku, J[Ku, JiYeon]; Sohn, JI[Sohn, Jung Inn]; Im, K[Im, Kyuhyun]; Jang, JE[Jang, Jae Eun]; Park, JJ[Park, Jong-Jin]; Kim, O[Kim, Ohyun]; Cha, S[Cha, SeungNam]; Park, YJ[Park, Young Jun]
- DGIST Authors
- Jang, JE[Jang, Jae Eun]
- Issue Date
- Energy and Environmental Science, 5(10), 8932-8936
- Article Type
- AC-DC Converters; Crystallography; Dielectric Films; Electrostatic Effect; Electrostatics; Light-Emitting Diodes; Liquid-Crystal Display Panels; Liquid Crystal Displays; Nanotechnology; Nanowires; Organic Light-Emitting Diodes (OLEDs); Output Current; Output Voltages; Piezoelectric Devices; Piezoelectricity; Sonic Waves; Substrate; Textile Industry; Textile Substrates; Textiles; Zinc; Zinc Oxide; ZnO Nanowires
- We have shown the enhanced piezoelectricity by electrostatic effects on a textile based platform. The electrostatic and piezoelectric effects were hybridized by integrating piezoelectric ZnO nanowires and a charged dielectric film on a wearable textile substrate. The hybrid textile nanogenerator produced an output voltage of 8 V and an output current of 2.5 μA. Using a simple AC-DC converter circuit, we operated the green organic light-emitting diode and a liquid crystal display panel using a 100 dB sonic wave. © 2012 The Royal Society of Chemistry.
- Royal Society of Chemistry
- Related Researcher
Jang, Jae Eun
Advanced Electronic Devices Research Group(AEDRG)
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