Excellent low-temperature activity for oxidation of benzene serials VOCs over hollow Pt/CoMn2O4 sub-nanosphere: Synergistic effect between Pt and CoMn2O4 on improving oxygen activation

Abstract

Constructing the interfacial active sites between noble metals and oxides is an effective way to enhancing the catalytic performance of noble metal-supported catalysts. Meanwhile, ultra-low dosage of the noble metal Pt but obtaining favorable catalytic activity is still major challenge to prepare noble metal-supported catalysts. Herein, the active Pt-CoMn2O4 interface with strong metal-support interaction (SMSI) is designed by loading ultra-low Pt content (0.12 wt%) on hollow structured CoMn2O4 sub-nanosphere (Pt/CoMn2O4). Compared with the reference MnOx, CoMn2O4 and Pt/MnOx, Pt/CoMn2O4 shows excellent catalytic activity even in presence of H2O, which is capable of completely converting toluene, ethylbenzene and o-xylene at 163, 207 and 218 °C, respectively. Various characterizations and density functional theory (DFT) calculations are performed to reveal the role of CoMn2O4 and specify the synergistic effect between Pt and CoMn2O4 on surface properties and catalytic performance. Intriguingly, in situ-designed temperature-programmed techniques and in situ Diffuse Reflectance Infrared Fourier Transform Spectroscopy clarify the substitution of Co in CoMn2O4 enhances oxygen mobility, and the interface of Pt and support is the active sites for gaseous oxygen activation can also be confirmed by DFT calculation results. This SMSI is prone to promote the supplement of active oxygen species that is essential for excellent low-temperature catalytic oxidation performance. This study provides a new insight into the design of high-performance noble metal catalysts, and the understanding of textural structure, active species, synergistic effect, and mechanisms of catalytic systems.