Adsorbed Oxygen Ions and Oxygen Vacancies; Their Concentration and Distribution in Metal Oxide Chemical Sensors and Influencing Role in Sensitivity and Sensing Mechanism

Çiftyürek, Engin; Li, Zheshen; Schierbaum, K.D.

doi:10.20944/preprints202212.0037.v1

2022

DOI: 10.20944/preprints202212.0037.v1

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Adsorbed Oxygen Ions and Oxygen Vacancies; Their Concentration and Distribution in Metal Oxide Chemical Sensors and Influencing Role in Sensitivity and Sensing Mechanism

Engin Çiftyürek¹,

Zheshen Li²,

K.D. Schierbaum³

Abstract: Oxidation reactions on semiconducting metal oxides (SMOs) surfaces have been extensively worked on in catalysis, fuel cells, and sensors. SMOs engaged powerfully in energy-related applications such as batteries, supercapacitors, solid oxide fuel cells (SOFCs), and chemical gas sensors. The deep understanding of SMO surface and oxygen interactions and defect engineering has become significant because all those mentioned applications are based on the adsorption/absorption and consumption/transportation of adsorb… Show more

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Cited by 8 publications

References 70 publications

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Investigating the Metallic Nanoparticles Decoration on Reduced Graphene Oxide-Based Sensors Used to Detect Sulfur Dioxide

Ruiz,

Varenne,

De Lima

et al. 2024

Chemosensors

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This paper presents the impact of the decoration of reduced graphene oxide (rGO) with metallic nanoparticles to detect sulfur dioxide (SO2). Copper and platinum were employed to produce metal nanoparticles (NPs) for the chemical and physical decoration of rGO to form the nanocomposites (rGO/NPs). We optimized NP loading by varying the concentrations of metal ions and deposition times for chemical and physical decoration, respectively. The chemical decoration presents a random nanoparticle distribution on the rGO surface with a broad particle size distribution (1 to 100 nm with a majority less than 40 nm). In comparison, the physical decoration presents uniformly distributed nanoparticles with particles of a size between 1 and 20 nm, with a majority less than 10 nm. The chemically decorated structures present the best gas responses and show that lower NP loading provides better responses. The nanocomposites present responses owing to a better synergy between NPs and the rGO surface, combined with the catalytic action of the NPs on the rGO. The physical decoration allows higher NP surface coverage than the chemical one but implies a lower remaining rGO naked surface for gaseous molecule interaction. These results illustrate that the NPs’ surface and the uncovered rGO contribute to the gas response.

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Investigating the Metallic Nanoparticles Decoration on Reduced Graphene Oxide-Based Sensors Used to Detect Sulfur Dioxide

Ruiz,

Varenne,

De Lima

et al. 2024

Chemosensors

View full text Add to dashboard Cite

show abstract

Construction of Hybrid ZnO/SnO2 n–n Heterojunction with Hierarchical Porous Biomorphic Nanostructure as a High-Response Sensor for Methanol Gas

Liu,

Yang,

Liu

et al. 2024

Crystals

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A novel hierarchical porous biomorphic ZnO/SnO was facilely synthesized in one step using bagasse as a bio-template. The structural features of the ZnO/SnO2 n–n heterostructures were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), and X-ray photoelectron spectroscopy (XPS). The results revealed that the as-prepared ZnO/SnO2 retained the original pore morphology of the bagasse material, and the ZnO/SnO2 was demonstrated with higher sensing performance as compared with the pure SnO2. Particularly, when the molar ratio of SnO2:ZnO = 1:1, the sensor displayed the highest response, showing an excellent response value of 37 under 100 ppm methanol at 340 °C. Meanwhile, the ZnO/SnO2 composite exhibited good gas selectivity and stability to methanol, which could mainly be attributed to the formation of n-n junctions between SnO2 and ZnO and the high capability of absorbed oxygen species of the ZnO/SnO2 composite.

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Geosmin and 2-Methylisoborneol Detection in Water Using Semiconductor Gas Sensors

Szczurek,

Maciejewska,

Kabsch-Korbutowicz

et al. 2023

Electronics

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Geosmin and 2-methylisoborneol (MIB) are the most common causes of unpleasant odours in drinking water. A method was proposed to detect and recognise these compounds in water and determine their concentrations. The method utilises commercial solid-state gas sensors and data analysis. Sample preparation plays an important role. The aqueous solution is converted into a gas sample using a specially designed dynamic headspace. The responses of the sensors are recorded during exposure to headspace vapours in a dynamic mode. The best limit of detection for geosmin, LOD = 6.20 µg/L, was attained with a TGS2602 sensor. The best limit of detection for MIB, LOD = 0.52 µg/L, was attained with a TGS826 sensor. Geosmin and MIB recognition was 100% successful based on TGS826 and TGS2602 response classifications. Geosmin and MIB concentrations were effectively determined in solutions containing one or both compounds. The respective mathematical models utilised the responses of TGS826 and TGS2602. The smallest concentration prediction error was RMSE = 2.19 µg/L (for geosmin) and RMSE = 0.33 µg/L (for MIB). The study demonstrated the application potential of non-specific gas sensors for the early warning monitoring of geosmin and MIB presence in water. Further studies are needed to develop a system that can be tested in field conditions.

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Adsorbed Oxygen Ions and Oxygen Vacancies; Their Concentration and Distribution in Metal Oxide Chemical Sensors and Influencing Role in Sensitivity and Sensing Mechanism

Cited by 8 publications

References 70 publications

Investigating the Metallic Nanoparticles Decoration on Reduced Graphene Oxide-Based Sensors Used to Detect Sulfur Dioxide

Investigating the Metallic Nanoparticles Decoration on Reduced Graphene Oxide-Based Sensors Used to Detect Sulfur Dioxide

Construction of Hybrid ZnO/SnO2 n–n Heterojunction with Hierarchical Porous Biomorphic Nanostructure as a High-Response Sensor for Methanol Gas

Geosmin and 2-Methylisoborneol Detection in Water Using Semiconductor Gas Sensors

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