4.3 Article

Temperature and Ambient Band Structure Changes in SnO2 for the Optimization of Hydrogen Response

期刊

INORGANICS
卷 11, 期 3, 页码 -

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MDPI
DOI: 10.3390/inorganics11030096

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tin dioxide; sensors; DFT; experiments

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Tin dioxide (SnO2) is extensively used for high-temperature sensing applications. This study investigates the impact of unintentional doping from precursors and intrinsic defects on the properties of SnO2 sensors. Experimental methods including sol-gel and spin-coating were used to synthesize low-cost SnO2 thin films, while theoretical simulations based on density functional theory (DFT) were conducted to examine the changes in electronic properties. The findings indicate that doping has a significant influence on gas sensor performance as well as the overall properties of SnO2.
Tin dioxide (SnO2) is one of the most used materials for sensing applications operating at high temperatures. Commonly, undoped SnO2 is made by precursors containing elements that can have a deleterious impact on the operation of SnO2 sensors. Here, we employ experimental and theoretical methods to investigate the structural properties and electronic structure of the rutile bulk and surface SnO2, focusing on unintentional doping due to precursors. Unintentional doping from precursors as well as intrinsic doping can play an important role not only on the performance of gas sensors, but also on the properties of SnO2 as a whole. The theoretical calculations were performed using density functional theory (DFT) with hybrid functionals. With DFT we examine the changes in the electronic properties of SnO2 due to intrinsic and unintentional defects and we then discuss how these changes affect the response of a SnO2-based gas sensor. From an experimental point of view, we synthesized low-cost SnO2 thin films via sol-gel and spin-coating processes. To further enhance the performance of SnO2, we coated the surface with a small amount of platinum (Pt). The crystalline structure of the films was analyzed using x-ray diffraction (XRD) and scanning electron microscopy (SEM), while for the determination of the elements contained in the sample, X-ray photoelectron spectroscopy (XPS) measurements were performed. Furthermore, we investigated the effect of temperature on the band structure of SnO2 in air, in a vacuum and in nitrogen and hydrogen chemical environments. To optimize the response, we used current-voltage characterization in varying environments. The aim is to associate the response of SnO2 to various environments with the changes in the band structure of the material in order to gain a better understanding of the response mechanism of metal oxides in different pressure and temperature environments. We found that the resistance of the semiconductor decreases with temperature, while it increases with increasing pressure. Furthermore, the activation energy is highly affected by the environment to which the thin film is exposed, which means that the thin film could respond with lower energy when exposed to an environment different from the air.

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