1. Highly Selective, ppb-Level Xylene Gas Detection by Sn2+-Doped NiO Flower-Like Microspheres Prepared by a One-Step Hydrothermal Method.
- Author
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Lu, Shaohe, Hu, Xuefeng, Zheng, Hua, Qiu, Junwen, Tian, Renbing, Quan, Wenjing, Min, Xinjie, Ji, Peng, Hu, Yewei, Cheng, Suishi, Du, Wei, Chen, Xiaoqiang, Cui, Beiliang, Wang, Xiaorong, and Zhang, Wei
- Subjects
MICROSPHERES ,XYLENE ,POISONOUS gases ,CARRIER density ,REACTIVE oxygen species ,DETECTION limit - Abstract
Detecting xylene gas is an important means of avoiding human harm from gas poisoning. A precise measurement demands that the gas sensor used must have high sensitivity, high selectivity, and low working temperature. To meet these requirements, in this study, Sn
2+ -doped NiO flower-like microspheres (SNM) with different amounts of Sn2+ synthesized by a one-step hydrothermal process were investigated. The responses of gas sensors based on different Sn2+ -doped NiO materials for various targeting gases were fully characterized. It was found that all of the synthesized materials exhibited the best gas response at a working temperature of 180 degrees, which was much lower than the previously reported working temperature range of 300–500 degrees. When exposed to 10 ppm xylene, the 8 at% Sn2+ -doped NiO sensor (mol ratio) exhibited the highest response, with a value of 30 (Rg /Ra ). More significantly, the detection limit of the 8 at% Sn2+ -doped NiO sensor for xylene is down in the ppb level. The Sn2+ -doped NiO material also exhibits excellent selectivity for other gases with long-term stability and repeatability. The significant improvement in the response to xylene can theoretically be attributed to a decrease in the intrinsic hole carrier concentration, higher amounts of adsorbed oxygen and active sites. [ABSTRACT FROM AUTHOR]- Published
- 2019
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