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Tandem Reaction on Ru/Cu-CHA Catalysts for Ammonia Elimination with Enhanced Activity and Selectivity

Qi An, Mengyuan Zhang, Jianhua Liu, Tingxu Chen, Yueqing He, Diru Liu, Yunbo Yu, Guangyan Xu, Hong He

2025Environmental Science & Technology16 citationsDOI

Abstract

Ammonia emissions from vehicles and power plants cause severe environmental issues, including haze pollution and nitrogen deposition. Selective catalytic oxidation (SCO) is a promising technology for ammonia abatement, but current catalysts often struggle with insufficient activity and poor nitrogen selectivity, leading to the formation of secondary pollutants. In this study, we developed a bifunctional Ru/Cu-CHA zeolite catalyst for ammonia oxidation, incorporating both SCO sites (Ru) and selective catalytic reduction sites (SCR, Cu). Various characterizations, including HAADF-STEM, XAFS, and H 2 -TPR, revealed that Cu 2+ cations are dispersed within the CHA zeolite, while RuO x clusters and nanoparticles are present both inside and on the surface of the zeolite. Operando DRIFTS-MS, in situ Raman spectroscopy, and DFT calculations confirmed that NH 3 adsorbed on Cu 2+ Lewis acid sites efficiently reduced RuO 2 with a lower energy barrier, significantly enhancing the low-temperature activity of the Ru/Cu-CHA catalyst. Additionally, Cu 2+ cations further facilitated the elimination of byproducts (NO x ) via the tandem SCR reaction, thus greatly improving the nitrogen selectivity. This synergistic effect contributed to high catalytic activity (>94% at 200 °C) and excellent nitrogen selectivity (>90% even at high temperatures above 325 °C) for Ru 2.5 /Cu-CHA during practical ammonia elimination in the presence of NO x and water vapor.

Topics & Concepts

CatalysisChemistryNOxInorganic chemistrySelectivityZeoliteSelective catalytic reductionAmmoniaAdsorptionBifunctionalOrganic chemistryCombustionCatalytic Processes in Materials ScienceAmmonia Synthesis and Nitrogen ReductionAdvanced Photocatalysis Techniques