Overview on conductometric solid-state gas dosimeters

Marr, Isabella; Groß, Andrea; Moos, Ralf

doi:10.5194/jsss-3-29-2014

Cited by 38 publications

(31 citation statements)

References 89 publications

(147 reference statements)

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“…As soon as the percolation threshold is reached, an abrupt increase of the conductivity is found, similar as in [17]. Furthermore, [25,26] found such an accumulative percolation behavior for conductometric NO x sensors when rare earth metals are transformed from carbonates into nitrates.…”

Section: Basic Resultssupporting

confidence: 66%

Why does the Conductivity of a Nickel Catalyst Increase during Sulfidation? An Exemplary Study Using an In Operando Sensor Device

Fremerey

Jess

Moos

2015

Sensors

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In order to study the sulfidation of a catalyst fixed bed, an in operando single pellet sensor was designed. A catalyst pellet from the fixed bed was electrically contacted and its electrical response was correlated with the catalyst behavior. For the sulfidation tests, a nickel catalyst was used and was sulfidized with H2S. This catalyst had a very low conductivity in the reduced state. During sulfidation, the conductivity of the catalyst increased by decades. A reaction from nickel to nickel sulfide occurred. This conductivity increase by decades during sulfidation had not been expected since both nickel and nickel sulfides behave metallic. Only by assuming a percolation phenomenon that originates from a volume increase of the nickel contacts when reacting to nickel sulfides, this effect can be explained. This assumption was supported by sulfidation tests with differently nickel loaded catalysts and it was quantitatively estimated by a general effective media theory. The single pellet sensor device for in operando investigation of sulfidation can be considered as a valuable tool to get further insights into catalysts under reaction conditions.

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Section: Basic Resultssupporting

confidence: 66%

Why does the Conductivity of a Nickel Catalyst Increase during Sulfidation? An Exemplary Study Using an In Operando Sensor Device

Fremerey

Jess

Moos

2015

Sensors

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“…The possibility to detect low gas concentrations by accumulation in the sensor or the direct detection of a gas dose are only two of their advantages [22].…”

Section: Introductionmentioning

confidence: 99%

Copper oxide based H2S dosimeters – Modeling of percolation and diffusion processes

Hennemann

Kohl

Smarsly

et al. 2015

Sensors and Actuators B: Chemical

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“…During the exposure to 10 ppm H 2 S, the conductance once again increases almost linearly, exhibiting an even sharper slope, remaining nearly constant after interrupting the H 2 S exposure. This behaviour is typical of a gas dosimeter, and cannot be attributed to surface reactions alone. It is noteworthy to mention that CuO, which is also used as sensor material for the detection of H 2 S, shows a similar behaviour at 150 °C.…”

Section: Resultsmentioning

confidence: 83%

Easy and Green Route towards Nanostructured ZnO as an Active Sensing Material with Unexpected H₂S Dosimeter‐Type Behaviour

et al. 2019

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Nanostructured ZnO particles were prepared through a straightforward, quick and low-temperature synthesis route involving coprecipitation of the metal precursor salts with oxalic acid, followed by hydrothermal treatment at 135 or 160°C. The synthesised nanostructured powders were thoroughly characterised by a wide array of analytical techniques from the morphological (Scanning Electron Microscopy -SEM-, Transmission Electron Microscopy -TEM-, Energy-dispersive Xray Spectroscopy -EDXS-), structural (Powder X-ray Diffraction [a] , Selected Area Electron Diffraction -SAED-), compositional (X-ray Photoelectron Spectroscopy -XPS-) and physical (thermal stability) point of view. As far as functional applications are concerned, the powders were tested as gas sensor materials for H 2 S detection. Thereby these ZnO particles showed unexpected gas dosimeter behaviour at 150°C. Based on these observations and on a comparison with literature a new model for the interaction of ZnO nanostructures with H 2 S is proposed.

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Overview on conductometric solid-state gas dosimeters

Cited by 38 publications

References 89 publications

Why does the Conductivity of a Nickel Catalyst Increase during Sulfidation? An Exemplary Study Using an In Operando Sensor Device

Why does the Conductivity of a Nickel Catalyst Increase during Sulfidation? An Exemplary Study Using an In Operando Sensor Device

Copper oxide based H2S dosimeters – Modeling of percolation and diffusion processes

Easy and Green Route towards Nanostructured ZnO as an Active Sensing Material with Unexpected H₂S Dosimeter‐Type Behaviour

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Overview on conductometric solid-state gas dosimeters

Cited by 38 publications

References 89 publications

Why does the Conductivity of a Nickel Catalyst Increase during Sulfidation? An Exemplary Study Using an In Operando Sensor Device

Why does the Conductivity of a Nickel Catalyst Increase during Sulfidation? An Exemplary Study Using an In Operando Sensor Device

Copper oxide based H2S dosimeters – Modeling of percolation and diffusion processes

Easy and Green Route towards Nanostructured ZnO as an Active Sensing Material with Unexpected H2S Dosimeter‐Type Behaviour

Contact Info

Product

Resources

About

Easy and Green Route towards Nanostructured ZnO as an Active Sensing Material with Unexpected H₂S Dosimeter‐Type Behaviour