Simplified synthesis of Pt-MnOx supported on three dimensional Co3O4 for catalytic removal of toluene

In this study, a simplified method was developed for synthesizing Pt-(MnOx)/three-dimensional (3D)-Co3O4 catalysts. This approach represents a convenient alternative to the typical procedure of initially synthesizing nanoparticles (NPs) and subsequently depositing them onto supports. The Pt1-(MnOx)1/3D Co3O4 catalyst, with a molar ratio of Pt:Mn=1:1, demonstrated excellent catalytic efficacy at a comparatively low reaction temperature and displayed commendable thermal stability during prolonged operation in the deep oxidation of toluene. The T90 (temperature required for 90 % conversion) of Pt1-(MnOx)1/3D Co3O4 was merely 163 °C. Characterization analysis revealed that the catalyst's remarkable catalytic efficiency is attributed to the elevated concentration of oxygen vacancy defects on Pt1-(MnOx)1/3D Co3O4 and its low-temperature reducibility. In situ DRIFTS analysis was conducted to investigate the possible reaction pathway of Pt1-(MnOx)1/3D Co3O4. The results indicated that the rapid dehydrogenation of methyl and the demethylation of toluene facilitate the cleavage of the benzene ring on the Pt1-(MnOx)1/3D Co3O4 catalyst, due to the abundant absorption of oxygen species. This process enhances the catalytic combustion of toluene. [Display omitted] •PtMn bimetallic nanoparticles on 3D Co3O4 were prepared by a simplified method.•The Pt1Mn1/Co3O4 showed the best activity (T90 = 167 °C) via tuning the Pt/Mn ratios.•The synergy of PtMn species on Co3O4 improves the performance for toluene oxidation.•The enhanced surface-adsorbed oxygen is responsible for the excellent activity.