• Deutschmann, Olaf
• Lott, Patrick
• Borchers, Michael

Abstract

In this work, two palladium-based catalysts with either ZSM-5 or Zeolite Y as support material are tested for their performance in selective catalytic reduction of NOx with hydrogen (H$_2$-SCR). The ligh-toff measurements in synthetic exhaust gas mixtures typical for hydrogen combustion engines are supplemented by detailed catalyst characterization comprising N$_2$ physisorption, X-ray powder diffraction (XRD), hydrogen temperature programmed reduction (H$_2$-TPR) and ammonia temperature programmed desorption (NH$_3$-TPD). Introducing 10% or 20% TiO2 into the catalyst formulations reduced the surface area and the number of acidic sites for both catalysts, however, more severely for the Zeolite Y-supported catalysts. The higher reducibility of the Pd particles that was uncovered by H$_2$-TPR resulted in an improved catalytic performance during the light-off measurements and substantially boosted NO conversion. Upon exposition to humid exhaust gas, the ZSM-5-supported catalysts showed a significant drop in performance, whereas the Zeolite Y-supported catalyst kept the high levels of conversion while shifting the selectivity from N$_2$O more toward NH$_3$ and N$_2$. The 1%Pd/20%TiO$_2$/HY catalyst subject to this work outperforms one of the most active and selective benchmark catalyst formulations, 1%Pd/5%V$_2$O$_5$/20%TiO$_2$-Al$_2$O$_3$, making Zeolite Y a promising support material for H$_2$-SCR catalyst formulations that allow efficient and selective NOx-removal from exhaust gases originating from hydrogen-fueled engines.

Topics

• surface
• x-ray diffraction
• Hydrogen
• combustion
• palladium
• temperature-programmed reduction