Layer-tunable synthesis of tetragonal Pr-doped SnO2 nanoplates for enhanced sensitive SO2 sensor

Layer-tunable synthesis of tetragonal Pr-doped SnO2 nanoplates for enhanced sensitive SO2 sensor

Nowadays SnO2 is widely used in manufacturing gas sensors for the detection of toxic and harmful gases such as SO2. However, SnO2 sensor still has the drawbacks of long recovery/response time and low response value. In this experiment, layer-tunable synthesis of tetragonal Pr-doped SnO2 nanoplates a...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Vol. 409; p. 135629
Main Authors: Zhang, Hao, Yu, Lingmin, Li, Ruijun, Zhao, Fan, Guo, Lei, Wang, Pu-hong, Cao, Wei, Ding, Zhi-jun, Qiao, Zhihong
Format: Journal Article
Language:English
Published: Elsevier B.V 15-06-2024
Subjects:
Gas sensors
Hydrothermal
Multi-layered tetragonal nanoplates
Pr-doped SnO2
SO2
Pr-doped SnO2
Multi-layered tetragonal nanoplates
Gas sensors
Hydrothermal
SO2
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Summary:Nowadays SnO2 is widely used in manufacturing gas sensors for the detection of toxic and harmful gases such as SO2. However, SnO2 sensor still has the drawbacks of long recovery/response time and low response value. In this experiment, layer-tunable synthesis of tetragonal Pr-doped SnO2 nanoplates are prepared by a feasible hydrothermal method. Observation at SEM reveals that the layer number increases and the interlayer spacing reduces with the increase of doping ratio of Pr (1, 3, 5 mol%). The gas sensing performance show that the three layer tetragonal structure of 1 mol% Pr-doped SnO2 sample with the extended interlayer spacing exhibits outstanding gas sensing performance to 5 ppm SO2 gas at 300℃, including excellent gas response (Ra/Rg = 2.4), fast gas adsorption and desorption equilibrium (15 s/16 s). This work reveals the significance of the layer number and interlayer spacing on the gas sensing characteristics, and the strategy of Pr dopant will promote the widespread application of SnO2 nanomaterials in SO2 gas sensors to figure out severe environmental problems. •Pr-SnO2 nanoplates composites were successfully prepared by a feasible water bath method.•A remarkably enhanced gas response to SO2 at 1–20 ppm was obtained compared with the pristine SnO2.•The gas sensing mechanism is discussed from the perspective of surface reaction.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2024.135629