Thickness Optimization of Highly Porous Flame-Aerosol Deposited WO3 Films for NO2 Sensing at ppb

Abegg, Sebastian; Cerrejon, David Klein; Güntner, Andreas T.; Pratsinis, Sotiris E.

doi:10.3390/nano10061170

Cited by 15 publications

(12 citation statements)

References 86 publications

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“…Flame spray pyrolysis (FSP) has emerged as a promising technology for industrial production of single-component and multicomponent metal-oxide nanomaterials. − The generated nanoparticles have wide applications including catalysts, , optical materials, sensors, , energy storage materials, , and biotechnology, etc. Different from the conventional vapor-fed aerosol flame synthesis (VAFS) method, − FSP can utilize less-volatile precursors, which significantly lower the cost and extend the versatility in elements.…”

Section: Introductionmentioning

confidence: 99%

Theoretical Single-Droplet Model for Particle Formation in Flame Spray Pyrolysis

2021

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In the current work, we develop a single droplet model to describe particle formation in multicomponentliquid droplet combustion. Both the gas-to-particle conversion and droplet-to-particle conversion routes of different solution properties are investigated, together with the population balance model and the droplet drying model. For multi-component droplets without precursors, the droplet combustion is limited by the species diffusion in the liquid phase. The model can well predict the droplet shrinkage history observed by previous PDA measurements. For the precursor with a low boiling point than its thermal decomposition temperature, the precursor in the droplet can then transform into nanoparticles through the gas-to-particle conversion route. The population balance model reveals that the generated nanoparticle size relies on both the precursor mass fraction and the residence time, which is consistent with the vaporfed aerosol flame synthesis. For the precursor that tends to decompose or precipitate in the liquid, it then undergoes the droplet-to-particle conversion route. The droplet behavior can be classified by the ratio of droplet evaporation time and precursor reaction or precipitation time. For small droplets with short evaporation time, the nanoparticle formation obeys the one-droplet-one-particle rule. For large droplets with long evaporation time, the competition among precipitation, thermal decomposition, and evaporation determines the final nanoparticle morphology. The single droplet model established in this study can potentially guide the precursor design and be coupled with the turbulent flame simulation of the whole flame spray pyrolysis burner.

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Section: Introductionmentioning

confidence: 99%

Theoretical Single-Droplet Model for Particle Formation in Flame Spray Pyrolysis

2021

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“…To put this result into perspective, we first note that an LoD of 3 ppb is on par with the best thin-film WO 3 -based MOS-type NO 2 sensors reported in the literature. 9 , 33 However, as the key distinctive feature and a step beyond this state of the art, our sensors exhibit this low ppb LoD in an environment where all molecular species are mixed (and not where the sensor is exposed sequentially to them 9 , 33 ), thereby truly emulating a real urban air environment.…”

Section: Resultsmentioning

confidence: 95%

Nanoplasmonic NO₂ Sensor with a Sub-10 Parts per Billion Limit of Detection in Urban Air

et al. 2022

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Urban air pollution is a critical health problem in cities all around the world. Therefore, spatially highly resolved real-time monitoring of airborne pollutants, in general, and of nitrogen dioxide, NO 2 , in particular, is of utmost importance. However, highly accurate but fixed and bulky measurement stations or satellites are used for this purpose to date. This defines a need for miniaturized NO 2 sensor solutions with detection limits in the low parts per billion range to finally enable indicative air quality monitoring at low cost that facilitates detection of highly local emission peaks and enables the implementation of direct local actions like traffic control, to immediately reduce local emissions. To address this challenge, we present a nanoplasmonic NO 2 sensor based on arrays of Au nanoparticles coated with a thin layer of polycrystalline WO 3 , which displays a spectral redshift in the localized surface plasmon resonance in response to NO 2 . Sensor performance is characterized under (i) idealized laboratory conditions, (ii) conditions simulating humid urban air, and (iii) an outdoor field test in a miniaturized device benchmarked against a commercial NO 2 sensor approved according to European and American standards. The limit of detection of the plasmonic solution is below 10 ppb in all conditions. The observed plasmonic response is attributed to a combination of charge transfer between the WO 3 layer and the plasmonic Au nanoparticles, WO 3 layer volume expansion, and changes in WO 3 permittivity. The obtained results highlight the viability of nanoplasmonic gas sensors, in general, and their potential for practical application in indicative urban air monitoring, in particular.

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“…This is in contrast to continuous thinner films (40 nm) of very similar composition (Pd 85 Au 15 ), which exhibit hysteresis [44]. Despite that other aerosol-based methods (e.g., flame synthesis [20,[71][72][73][74][75][76]) can be used to produce Pd-based nanoparticulate sensors, so far only spark ablation has been used to produce ANP-based materials for optical H 2 sensors.…”

Section: Materials Based On Aggregated Nanoparticlesmentioning

confidence: 99%

Thin Film and Nanostructured Pd-Based Materials for Optical H2 Sensors: A Review

Sousanis

Biskos

2021

Nanomaterials

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In this review paper, we provide an overview of state-of-the-art Pd-based materials for optical H2 sensors. The first part of the manuscript introduces the operating principles, providing background information on the thermodynamics and the primary mechanisms of optical detection. Optical H2 sensors using thin films (i.e., films without any nanostructuring) are discussed first, followed by those employing nanostructured materials based on aggregated or isolated nanoparticles (ANPs and INPs, respectively), as well as complex nanostructured (CN) architectures. The different material types are discussed on the basis of the properties they can attribute to the resulting sensors, including their limit of detection, sensitivity, and response time. Limitations induced by cracking and the hysteresis effect, which reduce the repeatability and reliability of the sensors, as well as by CO poisoning that deteriorates their performance in the long run, are also discussed together with an overview of manufacturing approaches (e.g., tailoring the composition and/or applying functionalizing coatings) for addressing these issues.

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Thickness Optimization of Highly Porous Flame-Aerosol Deposited WO3 Films for NO2 Sensing at ppb

Cited by 15 publications

References 86 publications

Theoretical Single-Droplet Model for Particle Formation in Flame Spray Pyrolysis

Theoretical Single-Droplet Model for Particle Formation in Flame Spray Pyrolysis

Nanoplasmonic NO₂ Sensor with a Sub-10 Parts per Billion Limit of Detection in Urban Air

Thin Film and Nanostructured Pd-Based Materials for Optical H2 Sensors: A Review

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Thickness Optimization of Highly Porous Flame-Aerosol Deposited WO3 Films for NO2 Sensing at ppb

Cited by 15 publications

References 86 publications

Theoretical Single-Droplet Model for Particle Formation in Flame Spray Pyrolysis

Theoretical Single-Droplet Model for Particle Formation in Flame Spray Pyrolysis

Nanoplasmonic NO2 Sensor with a Sub-10 Parts per Billion Limit of Detection in Urban Air

Thin Film and Nanostructured Pd-Based Materials for Optical H2 Sensors: A Review

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Product

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Nanoplasmonic NO₂ Sensor with a Sub-10 Parts per Billion Limit of Detection in Urban Air