Bi-doped urchin-like In2O3 hollow spheres: Synthesis and improved gas sensing and visible-light photocatalytic properties

[Display omitted] •Bi-doped urchin-like In2O3 hollow spheres were successfully synthesized.•The Bi-doped In2O3 ULSHs showed improved acetone sensing properties.•The Bi-doped In2O3 ULSHs also showed an upgraded photocatalytic performance. Developing metal oxide semiconductor (MOS) based functional na...

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Published inSensors and actuators. B, Chemical Vol. 321; p. 128623
Main Authors Tao, Zhenhua, Li, Yanwei, Zhang, Bo, Sun, Guang, Cao, Jianliang, Wang, Yan
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 15.10.2020
Elsevier Science Ltd
Subjects
Acetone
Acetone sensor
Bismuth
Crystal lattices
Doping
Element doping
Functional materials
Gas sensors
In2O3
Indium oxides
Linearity
Metal oxide semiconductors
Methylene blue
Nanomaterials
Photocatalysis
Selectivity
Sensors
Spheres
Urchin-like hollow
Visible-light photocatalysis
Acetone sensor
In2O3
Element doping
Urchin-like hollow
Spheres
Visible-light photocatalysis
Methylene blue
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Summary:[Display omitted] •Bi-doped urchin-like In2O3 hollow spheres were successfully synthesized.•The Bi-doped In2O3 ULSHs showed improved acetone sensing properties.•The Bi-doped In2O3 ULSHs also showed an upgraded photocatalytic performance. Developing metal oxide semiconductor (MOS) based functional nanomaterials through designing novel nanostructure and doping with foreign element has attracted an increasing interest due to their promising applications in various fields including but not limited to gas sensor and photocatalysis. In this paper, we demonstrated a facile sovothermal‒calcination route for synthesizing Bi-doped In2O3 urchin-like hollow spheres (ULHSs) and their upgraded gas sensing and visible-light photocatalytic performances. The successful doping Bi3+ into In2O3 crystal lattice was confirmed by various techniques. The results of gas sensing tests indicated that after doping In2O3 with Bi, an improved acetone sensitivity was achieved, especially in terms of higher response, faster response-recover speed and better selectivity. More importantly, the IBO-3 (the sample with an optimized molar ratio of Bi:In = 3:100) sensor also showed considerable humidity resistance and good response linearity within 0.3–5 ppm acetone, demonstrating its potential application in acetone sensor for monitoring exhaled breath. In addition, doping In2O3 with Bi also brought an improvement of visible-light photocatalytic performance. The reaction rate constant of IBO-3 for degrading methylene blue (MB) was about 4 times higher than that of the pure In2O3 counterpart.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2020.128623