Gas sensors are widely applied to monitor combustible and harmful gases which can be detrimental to safety, health and environment. SnO2, a wide gap semiconductor, is the most promising gas sensor material because of high chemical stability and low fabrication cost[1]. While due to the drawbacks of SnO2 working as gas sensing material, such as low selectivity and high working temperature, doping by noble or transition metals is a particularly efficient way to improve its sensing properties[2]. SnO2 doped by antimony (SnO2/Sb) is a typical n-type oxide material, which has high electrical conductivity and thermal stability.

Gas Sensing Properties Comparison between SnO 2 and Highly Antimony-Doped SnO 2 Materials

Zhifu Feng;Andrea Gaiardo;Giancarlo Pepponi;Pierluigi Bellutti;Matteo Valt;
2020-01-01

Abstract

Gas sensors are widely applied to monitor combustible and harmful gases which can be detrimental to safety, health and environment. SnO2, a wide gap semiconductor, is the most promising gas sensor material because of high chemical stability and low fabrication cost[1]. While due to the drawbacks of SnO2 working as gas sensing material, such as low selectivity and high working temperature, doping by noble or transition metals is a particularly efficient way to improve its sensing properties[2]. SnO2 doped by antimony (SnO2/Sb) is a typical n-type oxide material, which has high electrical conductivity and thermal stability.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11582/323348
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