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JOURNAL ARTICLE

Highly sensitive humidity sensor based on amorphous Al2O3nanotubes

Baochang ChengBaixiang TianCuicui XieYanhe XiaoShuijin Lei

Year: 2010 Journal:   Journal of Materials Chemistry Vol: 21 (6)Pages: 1907-1912   Publisher: Royal Society of Chemistry
DOI: 10.1039/c0jm02753g
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Abstract

Amorphous Al2O3 nanotubes were obtained by the transformation of NH4Al(OH)2CO3 nanotubes annealed at 600 °C. The tube-like nanostructures not only increase efficient sites for gas adsorption, but also promote the dissociation of water absorbed onto the surfaces of the nanotube walls. Moreover, they also provide effective and fast channels for vapor and liquid transport. Therefore, the sensors based on Al2O3 nanotubes show high sensitivity and fast response/recovery time to humidity. The impedance changes approximately four orders of magnitude as relative humidity (RH) varies from 11% to 95% at the measured frequency of 40 Hz. Additionally, the sensor also presents relatively small hysteresis and long-term stability. For low RH levels, the protonic conductor is dominant, whereas for increasing RH levels the ionic contribution becomes prevalent. This study demonstrates that Al2O3 nanotubes have promising applications in environmental monitoring.

Keywords:
Materials science Humidity Relative humidity Hysteresis Nanotube Amorphous solid Water vapor Adsorption Ionic bonding Chemical engineering Nanotechnology Dissociation (chemistry) Nanostructure Carbon nanotube Chemistry Physical chemistry Ion Organic chemistry Thermodynamics Condensed matter physics

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Cited By
4.64
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38
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0.96
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Citation History

Topics

Gas Sensing Nanomaterials and Sensors
Physical Sciences →  Engineering →  Electrical and Electronic Engineering
Analytical Chemistry and Sensors
Physical Sciences →  Chemical Engineering →  Bioengineering
ZnO doping and properties
Physical Sciences →  Materials Science →  Materials Chemistry

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