Electric Energy Storage Effect in Hydrated ZrO2-Nanostructured System

Electric Energy Storage Effect in Hydrated ZrO2-Nanostructured System

The dimensional effect of electric charge storage with a density of up to 270 μF/g by the hydrated ZrO2-nanoparticles system was determined. It was found that the place of localization of different charge carriers is the generalized heterophase boundary-nanoparticles surface. The supposed mechanism...

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Veröffentlicht in:Nanomaterials (Basel, Switzerland) Switzerland), 2022-05, Vol.12 (11), p.1783
Hauptverfasser: Doroshkevich, Alexander S., Lyubchyk, Andriy I., Oksengendler, Boris L., Zelenyak, Tatyana Yu, Appazov, Nurbol O., Kirillov, Andriy K., Vasilenko, Tatyana A., Tatarinova, Alisa A., Gorban, Oksana O., Bodnarchuk, Viktor I., Nikiforova, Nadejda N., Balasoiu, Maria, Mardare, Diana M., Mita, Carmen, Luca, Dorin, Mirzayev, Matlab N., Nabiyev, Asif A., Popov, Evgeni P., Stanculescu, Anca, Konstantinova, Tatyana E., Aleksiayenak, Yulia V.
Format: Artikel
Sprache:eng
Schlagworte:
Approximation
Band theory
Charge density
Current carriers
dimensional effects
Electric contacts
Electric energy storage
Electric fields
Electrodes
Electron states
Energy storage
Humidity
Leakage current
Localization
nano-ionic capacitors
Nanoelectronics
Nanoparticles
NMR
Nuclear magnetic resonance
Particle size
powder nanotechnologies
Zirconium dioxide
zirconium oxide
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Zusammenfassung:The dimensional effect of electric charge storage with a density of up to 270 μF/g by the hydrated ZrO2-nanoparticles system was determined. It was found that the place of localization of different charge carriers is the generalized heterophase boundary-nanoparticles surface. The supposed mechanism of the effect was investigated using the theory of dispersed systems, the band theory, and the theory of contact phenomena in semiconductors, which consists of the formation of localized electronic states in the nanoparticle material due to donor–acceptor interaction with the adsorption ionic atmosphere. The effect is relevant for modern nanoelectronics, microsystem technology, and printed electronics because it allows overcoming the basic physical restrictions on the size, temperature, and operation frequency of the device, caused by leakage currents.
ISSN:2079-4991
2079-4991
DOI:10.3390/nano12111783