Tuning the Metal–Support Interaction by Modulating CeO<sub>2</sub> Oxygen Vacancies to Enhance the Toluene Oxidation Activity of Pt/CeO<sub>2</sub> Catalysts
Dengfeng Yan, Xudong Li, Jinping Zhong, Quanming Ren, Yikui Zeng, Siyuan Gao, Peng Liu, Mingli Fu, Daiqi Ye
Abstract
In this research, a range of Pt/CeO 2 catalysts featuring varying Pt–O–Ce bond contents were developed by modulating the oxygen vacancies of the CeO 2 support for toluene abatement. The Pt/CeO 2 –HA catalyst generated a maximum quantity of Pt–O–Ce bonds (possessed the strongest metal–support interaction), as evidenced by the visible Raman results, which demonstrated outstanding toluene catalytic performance. Additionally, the UV Raman results revealed that the strong metal–support interaction stimulated a substantial increase in oxygen vacancies, which could facilitate the activation of gaseous oxygen to generate abundant reactive oxygen species accumulated on the Pt/CeO 2 –HA catalyst surface, a conclusion supported by the H 2 -TPR, XPS, and toluene-TPSR results. Furthermore, the results from quasi- in situ XPS, in situ DRIFTS, and DFT indicated that the Pt/CeO 2 –HA catalyst with a strong metal–support interaction led to improved mobility of reactive oxygen species and lower oxygen activation energies, which could transfer a large number of activated reactive oxygen species to the reaction interface to participate in the toluene oxidation, resulting in the relatively superior catalytic performance. The approach of tuning the metal–support interaction of catalysts offers a promising avenue to develop highly active catalysts for toluene degradation.