Abstract
Abstract. To meet today's emission standards, the ammonia-based selective catalytic reduction (SCR) has become the major NOx control strategy for light and heavy diesel engines. Before NOx reduction can proceed, adsorption of ammonia on the acidic sites of the catalyst is necessary. For improvements in efficiency and control of the exhaust gas aftertreatment, a better understanding of the ammonia storage on the acidic sites of zeolite-based SCR catalysts is needed. Thereby, the correlation of dielectric properties of the catalyst material itself with the ammonia storage is a promising approach. Recently, a laboratory setup using microwave cavity perturbation to measure the dielectric properties of catalyst material has been described. This study shows the first experimental data on zeolite-based SCR materials in their H-form. The SCR powder samples are monitored by microwave cavity perturbation while storing and depleting ammonia, both with and without admixed NOx at different temperatures. Its complex dielectric permittivity is found to correlate closely with the stored mass of ammonia. The influence of the temperature and the Si / Al ratio of the zeolite to the ammonia storage behavior are also examined. These measurements disclose different temperature dependencies and differing sensitivities to ammonia storage for both real and imaginary parts of the complex permittivity. The apparent constant sensitivity of the real part can be related to the polarity of the adsorbed ammonia molecules, whereas the imaginary part depends on the Si / Al ratio and is related to the conductivity mechanisms of the zeolite material by proton hopping. It provides information about the zeolite structure and the number of (and the distance between) acidic storage sites, in addition to the stored ammonia mass.
Highlights
The stringent regulations for emissions of nitrogen oxides (NOx) from combustion engines are a continuous factor in forcing automotive manufacturers to improve the efficiency of their exhaust gas aftertreatment systems
This is especially true for light- and heavy-duty diesel engines, which are operated leanly, where the ammonia-based selective catalytic reduction (SCR) has become the major NOx control strategy to meet emission standards like the upcoming Euro 6 (Johnson, 2009)
The total stored mass of NH3 decreases with increasing temperature for all Si / Al ratios because of the temperature-dependent adsorption (Niwa and Katada, 2013)
Summary
The stringent regulations for emissions of nitrogen oxides (NOx) from combustion engines are a continuous factor in forcing automotive manufacturers to improve the efficiency of their exhaust gas aftertreatment systems. Since the sample occupied most of the cavity volume (metal canning), these systems are suitable for real-world applications but not to characterize material properties owing to their very large perturbation of the sample on the cavity space, making the inversion analysis for extracting complex permittivity very difficult Instead, they are intended to detect the status of full-sized exhaust gas aftertreatment devices during operation on the road. In order to determine the dielectric properties of a catalyst material in operando, we have developed a laboratory test setup for catalyst powder characterization under reaction conditions by microwave cavity perturbation (introduced in Dietrich et al, 2014) It enables direct measurement of the complex permittivity of catalytic powder samples undergoing gas storage and catalytic reactions in a defined gas atmosphere, with gas analyzers upstream and downstream of the catalyst sample. It operates within a temperature range from room temperature (where usually no reactions occur) to 300 ◦C
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
