Mechanistic insight into the promoting effect of partial substitution of Mn by Ce on N2 selectivity of MnTiOx catalyst for NH3-SCR of NO

• Published in: Journal of the Taiwan Institute of Chemical Engineers Vol. 133
• Main Authors: Gao, Yu, Han, Zhitao, Zhai, Guangpeng, Song, Liguo, Dong, Jingming, Yang, Shaolong, Pan, Xinxiang
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.04.2022
• Subjects: Ce substitution; Metal oxides catalyst; N2 selectivity; Selective catalytic reduction; Metal oxides catalyst; Selective catalytic reduction; N2 selectivity; Ce substitution
• ISSN: 1876-1070; 1876-1089
• DOI: 10.1016/j.jtice.2022.104269

•The partial substitution of Mn by Ce significantly enhanced N2 selectivity.•It resulted in a mild redox property and an enhanced surface acidity.•It led to the formation of NH4NO2 and the consumption of -NH2 on catalyst surface.•It inhibited the oxidation reaction of NH3 species via L-H mechanism. Owing to excellent low-temperature activity and environmentally friendliness, Mn-based catalyst is commonly considered as one of the promising alternatives to traditional V-based catalysts for NH3-SCR of NO. However, Mn-based catalysts still suffer from some drawbacks, such as poor N2 selectivity and narrow operating temperature window. Herein, MnTiOx catalyst was synthesized through a facile coprecipitation method. Ce was adopted to partially substitute Mn in MnTiOx catalyst to promote N2 selectivity and high-temperature activity. The partial substitution of Mn by Ce in MnTiOx catalyst could significantly improve N2 selectivity and widen operating temperature window. The higher substitution rate of Mn by Ce was, the better N2 selectivity of Ce MnTiOx catalyst was. Partial substitution of Mn by Ce led to mild redox property, enhanced surface acidity, lower surface Mn4+ and chemisorbed oxygen species proportion on catalyst surface. Besides, partial substitution of Mn by Ce was in favor of the generation NH4NO2 species in NH3 oxidation reaction, and boosted the consumption of -NH2 species during NH3-SCR reaction, which was conducive to N2 formation. The reactions between adsorbed NH3 species and oxygen species through Langmuir-Hinshelwood mechanism might be inhibited by partial substitution of Mn by Ce, thus effectively restraining N2O formation. [Display omitted]