Hydrothermal synthesis of ultrathin ZnO nanosheets and their gas-sensing properties

Weiwei Guo; Tianmo Liu; Zhongping Gou; Wen Zeng; Yong Chen; Zhongchang Wang

doi:10.1007/s10854-012-1009-x

Hydrothermal synthesis of ultrathin ZnO nanosheets and their gas-sensing properties

Weiwei Guo^*
, Tianmo Liu
, Zhongping Gou
, Wen Zeng
, Yong Chen
, Zhongchang Wang

^*Corresponding author for this work

Chongqing University
Tohoku University

Research output: Contribution to journal › Article › peer-review

16 Scopus citations

Abstract

Gas-sensing performances can often be enhanced significantly once the size of sensing nanomaterials approaches a critical value of 15 nm. Here, we synthesize, by a simple hydrothermal method accompanied by the calcination process, ultrathin ZnO nanosheets with a thickness as thin as 10-13 nm. We find that the prepared zinc hydroxide carbonate precursor is largely agglomerated, yet transformed to the ultrathin ZnO nanosheets in a dispersive fashion after the calcination process. The as-prepared ultrathin nanosheets exhibit excellent gas-sensing functions to ethanol gas at the optimal temperature as low as 300 C under the concentration of 50 ppm, rendering them a promising sensing material for the on-site detection of ethanol.

Original language	English
Pages (from-to)	1764-1769
Number of pages	6
Journal	Journal of Materials Science: Materials in Electronics
Volume	24
Issue number	6
DOIs	https://doi.org/10.1007/s10854-012-1009-x
State	Published - Jun 2013
Externally published	Yes

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title = "Hydrothermal synthesis of ultrathin ZnO nanosheets and their gas-sensing properties",

abstract = "Gas-sensing performances can often be enhanced significantly once the size of sensing nanomaterials approaches a critical value of 15 nm. Here, we synthesize, by a simple hydrothermal method accompanied by the calcination process, ultrathin ZnO nanosheets with a thickness as thin as 10-13 nm. We find that the prepared zinc hydroxide carbonate precursor is largely agglomerated, yet transformed to the ultrathin ZnO nanosheets in a dispersive fashion after the calcination process. The as-prepared ultrathin nanosheets exhibit excellent gas-sensing functions to ethanol gas at the optimal temperature as low as 300 C under the concentration of 50 ppm, rendering them a promising sensing material for the on-site detection of ethanol.",

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T1 - Hydrothermal synthesis of ultrathin ZnO nanosheets and their gas-sensing properties

AU - Guo, Weiwei

AU - Liu, Tianmo

AU - Gou, Zhongping

AU - Zeng, Wen

AU - Chen, Yong

AU - Wang, Zhongchang

PY - 2013/6

Y1 - 2013/6

N2 - Gas-sensing performances can often be enhanced significantly once the size of sensing nanomaterials approaches a critical value of 15 nm. Here, we synthesize, by a simple hydrothermal method accompanied by the calcination process, ultrathin ZnO nanosheets with a thickness as thin as 10-13 nm. We find that the prepared zinc hydroxide carbonate precursor is largely agglomerated, yet transformed to the ultrathin ZnO nanosheets in a dispersive fashion after the calcination process. The as-prepared ultrathin nanosheets exhibit excellent gas-sensing functions to ethanol gas at the optimal temperature as low as 300 C under the concentration of 50 ppm, rendering them a promising sensing material for the on-site detection of ethanol.

AB - Gas-sensing performances can often be enhanced significantly once the size of sensing nanomaterials approaches a critical value of 15 nm. Here, we synthesize, by a simple hydrothermal method accompanied by the calcination process, ultrathin ZnO nanosheets with a thickness as thin as 10-13 nm. We find that the prepared zinc hydroxide carbonate precursor is largely agglomerated, yet transformed to the ultrathin ZnO nanosheets in a dispersive fashion after the calcination process. The as-prepared ultrathin nanosheets exhibit excellent gas-sensing functions to ethanol gas at the optimal temperature as low as 300 C under the concentration of 50 ppm, rendering them a promising sensing material for the on-site detection of ethanol.

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JO - Journal of Materials Science: Materials in Electronics

JF - Journal of Materials Science: Materials in Electronics

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Hydrothermal synthesis of ultrathin ZnO nanosheets and their gas-sensing properties

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