Gas sensing enhancing mechanism via doping-induced oxygen vacancies for gas sensors based on indium tin oxide nanotubes

[Display omitted] •Indium tin oxide nanotubes with different Sn doping concentrations were synthesized by electrospinning.•A specific response has been proposed to better characterize the sensing performances of gas sensors.•Facilitated transport channel for electrons can benefit the decrease in wor...

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Published in:Sensors and actuators. B, Chemical Chemical, 2018-07, Vol.265, p.273-284
Main Authors: Zhou, Jin Yuan, Bai, Jing Long, Zhao, Hao, Yang, Zhen Yu, Gu, Xiu Yun, Huang, Bao Yu, Zhao, Chang Hui, Cairang, Limao, Sun, Geng Zhi, Zhang, Zhen Xing, Pan, Xiao Jun, Xie, Er Qing
Format: Article
Language:English
Subjects:
Aldehydes
Ambience
Detection
Doping
Electrospinning
Formaldehyde
Gas detectors
Gas sensors
Indium oxides
Indium tin oxide
Indium tin oxides
Nanoparticles
Nanotubes
Oxygen
Oxygen vacancies
Tin
Tin oxides
Vacancies
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Summary:[Display omitted] •Indium tin oxide nanotubes with different Sn doping concentrations were synthesized by electrospinning.•A specific response has been proposed to better characterize the sensing performances of gas sensors.•Facilitated transport channel for electrons can benefit the decrease in working temperatures.•Oxygen vacancies can mainly affect the sensitivity of gas sensor. It’s demonstrated that the defects induced by doping can greatly influence the sensing properties of oxide-based gas sensors. In this work, the authors have designed indium tin oxide nanotubes (ITO NTs) with different Sn doping concentrations. Results showed that the walls of ITO NTs are comprised of the formed ITO and redundant In2O3 nanoparticles (NPs) at low doping concentration, and the doping-induced oxygen vacancies (Vo··S) can be tuned by Sn concentrations. Series of sensing tests to formaldehyde gas indicated that the ITO-7 NTs show the lowest working temperature (160 °C) and the highest specific response. Here, It is noted that to eliminate the influence of the coating amount of sensing performances, a concept of specific response was proposed i.e., Rair/(m–Rgas), where Rair and Rgas respectively stand for the resistances of gas sensors in the reference gas (in air this case) and in the test gas ambience, and m stands for the mass of the coated sensing materials. The decreased working temperature could be attributed to the formed In2O3 NPs/ITO tubular structure, and the enhanced specific response might be mainly associated with the Vo··S. Furthermore, a possible gas sensing enhancing mechanism via Vo··S for ITO-based gas sensors was proposed based on our results and analysis. This research would give some instructive advice to design high-performances oxide-based gas sensors via tuning the Vo··S.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2018.03.008