Collaborative optimization of de-NOx & NH4HSO4 decomposition over Cu-based LDO catalysts: Perspective from the acidic and redox properties

Abstract

Low temperature de-NOx catalyst with excellent resistance to ammonium bisulfate (ABS) is of great practical significance. Study about the simultaneous optimization of de-NOx performance and ABS resistance by acidic and redox properties regulation is imperative. In this work, the influence of the acidic and redox properties to the de-NOx & ABS decomposition performance was investigated via three Cu-based LDO model catalysts with distinct surface chemical character. Test results indicated that the low temperature de-NOx performance of both the modified Cu2NiAl-LDO and Cu2CoAl-LDO catalysts was slightly improved, while their in situ ABS resistance behavior was remarkably different (Cu2CoAl-LDO > Cu3Al-LDO > Cu2NiAl-LDO). TPDC and TPSR test evidenced that the ABS thermal decomposition or its reactivity with NOx was facilitated over Cu2CoAl-LDO catalyst, but inhibited over Cu2NiAl-LDO catalyst. Characterizations revealed the Cu2CoAl-LDO catalyst with stronger redox property could contribute to ABS decomposition, while more weak acid sites on Cu2NiAl-LDO catalyst induced a negative effect for ABS decomposition. Our study might provide guidance on the rational design of de-NOx & anti-ABS catalysts for future studies.