The electrical properties of NOx-storing carbonates during NOx exposure

The electrical properties of NOx-storing carbonates during NOx exposure

In order to gain a deeper understanding of the different components in multi-component automotive catalyst systems and integrating type NOx-sensors, in-situ electrical methods are examined. The conductivity of BaCO3 and K2CO3, key components in automotive NOx storage catalysts, was examined as a fun...

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Bibliographic Details
Published in:Solid state ionics Vol. 225; pp. 317 - 323
Main Authors: Groß, A., Bishop, S.R., Yang, D.J., Tuller, H.L., Moos, R.
Format: Journal Article
Language:English
Published: Elsevier B.V 04-10-2012
Subjects:
Automotive components
Barium carbonate
Carbonates
Catalysts
Electrical properties
Electrical resistivity
Gas composition
In-situ characterization
Lean NOx traps
Nitrogen dioxide
NOx storage
Potassium carbonate
Resistivity
Sorption
NOx storage
In-situ characterization
Lean NOx traps
Barium carbonate
Electrical properties
Potassium carbonate
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Summary:In order to gain a deeper understanding of the different components in multi-component automotive catalyst systems and integrating type NOx-sensors, in-situ electrical methods are examined. The conductivity of BaCO3 and K2CO3, key components in automotive NOx storage catalysts, was examined as a function of gas composition and temperature. Impedance measurements performed on BaCO3, K2CO3, and equimolar mixtures of both, demonstrated that, in all cases, the resistance decreases in the presence of NO2 gas with progressive NOx sorption on the carbonate surface. Mixing the hygroscopic but low resistivity K2CO3 with the very highly resistive but stable BaCO3 resulted in greater stability than K2CO3 alone, as well as improved ability to measure resistivity changes. The resistance of the mixture recovered about 50% of its value after removing NO2 from the gas stream, believed to result from migration of sorbed NOx from K to Ba, instead of desorption alone. These results on NOx trap materials show that in-situ impedance spectroscopy measurements offer real-time characterization of NOx loading levels in lean NOx trap catalyst components. ► In-situ investigation of carbonate lean NOx traps via impedance spectroscopy. ► Conductivity and activation energy of BaCO3 and Ba(NO3)2 in the range of 300–550°C. ► Conductivity increases reversible sorbing NO2 on BaCO3 or K2CO3. ► Stepwise NOx accumulation detected electrically. ► K2CO3 dominates in mixture due to 5 orders of lower conductivity.
Bibliography:ObjectType-Article-2
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content type line 23
ISSN:0167-2738
1872-7689
DOI:10.1016/j.ssi.2012.05.009