Electronic noses based on metal oxide nanowires: A review

Tonezzer, Matteo; Le, Dang Thi Thanh; Duy, Lai Van; Hòa, Nguyễn Đức; Gasperi, F.; Duy, Nguyễn Văn; Biasioli, Franco

doi:10.1515/ntrev-2022-0056

Cited by 23 publications

(22 citation statements)

References 88 publications

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“…The chemical species of the copper surface after oxidation were studied using the XPS observation (Figure 4f). The intensities of cuprous oxide (Cu 2 O) peaks at 932.2 eV are much higher than copper oxide (CuO) peaks at 934.3 eV as seen from Cu 2p3/2 spectra 33 . Based on XPS results, it is implied that cuprous oxide (Cu 2 O) mainly appears on the surface of copper in the oxidation process, 34 which is consistent with the XRD patterns above.…”

Section: Resultssupporting

confidence: 80%

“…The intensities of cuprous oxide (Cu 2 O) peaks at 932.2 eV are much higher than copper oxide (CuO) peaks at 934.3 eV as seen from Cu 2p3/2 spectra. 33 Based on XPS results, it is implied that cuprous oxide (Cu 2 O) mainly appears on the surface of copper in the oxidation process, 34 which is consistent with the XRD patterns above. As a result of the oxidation process, cuprous oxide became the available sites for silane coupling agent to graft functional groups on the oxidized copper surface.…”

Section: Analysis On Peel Strength and Bonding Mechanismsupporting

confidence: 73%

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Enhancing peel strength between liquid crystal polymer and copper with plasma treatment, surface oxidation, and silane coating

Chen

Feng

et al. 2022

J of Applied Polymer Sci

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Liquid crystal polymer (LCP) has been employed as a major type of substrate in flexible printed circuit manufacturing due to its excellent electrical and mechanical properties. In order to improve the peel strength of LCP to copper, a three‐step process was proposed in this study. In the process, the surface of LCP was treated with oxygen plasma to create holes and increase the number of hydrophilic groups. The surface of copper was then oxidized and coated with silane coupling agent. Above surface treatment aimed to introduce amine group to facilitate the interconnection between copper and LCP and improve the surface roughness of the copper surface. The final samples were laminated by the above treated copper and LCP. In this study, different oxidation conditions were explored to analyze the morphology and composition of the copper surface after oxidation. The maximum peel strength of the sample prepared by this process was 8.92 N cm−1. This developed process can effectively reduce product thickness compared to current methods in industry and can reduce lamination temperature compared to previous studies.

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Section: Resultssupporting

confidence: 80%

Section: Analysis On Peel Strength and Bonding Mechanismsupporting

confidence: 73%

Enhancing peel strength between liquid crystal polymer and copper with plasma treatment, surface oxidation, and silane coating

Chen

Feng

et al. 2022

J of Applied Polymer Sci

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“…Among them, SMOs have been widely used as gas-sensing layers due to their superior gas sensitivity at elevated temperatures. − In particular, nanostructured materials have been actively investigated in the gas sensor . Thus far, different synthetic methods for porous nanostructured SMOs have been reported including electrospinning, ,− spray pyrolysis, hydrothermal, solvothermal, , and direct precipitation. , On the other hand, various techniques to overcome their poor intrinsic gas selectivity have been suggested including functionalization with catalysts, − defect creation, phase control, and coating with selectivity overlayer. ,, Many publications ,− summarizing the performance of state-of-the-art SMOs concerning sensitivity, selectivity, sensing mechanisms, and morphology engineering have been widely reported.…”

Section: Introductionmentioning

confidence: 99%

Review on Porosity Control in Nanostructured Semiconducting Metal Oxides and Its Influence on Chemiresistive Gas Sensing

Bulemo

Cheong

2023

ACS Appl. Nano Mater.

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Nanostructured semiconducting metal oxides (SMOs) hold the potential for playing a critical role in gas-sensing applications due to their interconnected nanograins, large surface area, and shorter diffusion length. The rational introduction of ubiquitous porosity in SMOs can enhance gas/air diffusion as well as the accessibility of nanograins and reactive sites. Although much work has been researched for adopting highly porous nanostructured SMOs to enhance gas sensing, no comprehensive review on porosity control has yet been presented. In this review, the latest porosity control methods for SMOs, structural properties, and their gas-sensing results are reported. Finally, perspective on porosity control methods and future directions are provided for further development and research of porous SMO-based gas-sensing nanomaterials.

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“…Although SnO 2 is one of the metal oxides with the best properties and therefore most used for gas sensors, even the finest nanostructures such as cross-linked porous nanosheets [ 20 ] and hollow nanoparticles [ 21 ] exhibit very similar responses to these two gases, making them difficult to distinguish. Therefore, chemoresistors are usually joined in arrays called electronic noses, which exploit different materials to obtain good selectivity [ 22 , 23 ]. The interest in electronic noses leads to the study of the most innovative materials, such as graphene and graphene oxide, and the use of algorithms such as the support vector machine (SVM) allows one to obtain good quantitative results [ 24 ].…”

Section: Introductionmentioning

confidence: 99%

Nanosensor Based on Thermal Gradient and Machine Learning for the Detection of Methanol Adulteration in Alcoholic Beverages and Methanol Poisoning

Tonezzer

Bazzanella

Gasperi

et al. 2022

Sensors

Self Cite

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Methanol, naturally present in small quantities in the distillation of alcoholic beverages, can lead to serious health problems. When it exceeds a certain concentration, it causes blindness, organ failure, and even death if not recognized in time. Analytical techniques such as chromatography are used to detect dangerous concentrations of methanol, which are very accurate but also expensive, cumbersome, and time-consuming. Therefore, a gas sensor that is inexpensive and portable and capable of distinguishing methanol from ethanol would be very useful. Here, we present a resistive gas sensor, based on tin oxide nanowires, that works in a thermal gradient. By combining responses at various temperatures and using machine learning algorithms (PCA, SVM, LDA), the device can distinguish methanol from ethanol in a wide range of concentrations (1–100 ppm) in both dry air and under different humidity conditions (25–75% RH). The proposed sensor, which is small and inexpensive, demonstrates the ability to distinguish methanol from ethanol at different concentrations and could be developed both to detect the adulteration of alcoholic beverages and to quickly recognize methanol poisoning.

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Electronic noses based on metal oxide nanowires: A review

Cited by 23 publications

References 88 publications

Enhancing peel strength between liquid crystal polymer and copper with plasma treatment, surface oxidation, and silane coating

Enhancing peel strength between liquid crystal polymer and copper with plasma treatment, surface oxidation, and silane coating

Review on Porosity Control in Nanostructured Semiconducting Metal Oxides and Its Influence on Chemiresistive Gas Sensing

Nanosensor Based on Thermal Gradient and Machine Learning for the Detection of Methanol Adulteration in Alcoholic Beverages and Methanol Poisoning

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