While utilization of transitional metals as a promoter has been extensively studied to enhance the activity of Pt-based catalysts for the oxidation of formaldehyde (HCHO), there is still a lack of well elucidated property−function relationship for the rational selection of a promoter in catalyst design. Herein, we modified a Pt/ CeO 2 catalyst with two transitional metal dopants (i.e., Mn and Cu) that showed negligible influence on the physical structure of the Pt− CeO 2 matrix but distinct effects on the activity of the catalyst. Complementary characterizations combined with density functional theory modeling revealed that the transitional metal dopants significantly modified the electronic structure of the catalyst and shifted the d-band of Pt to higher energy with different extents, which may tune the bonding strength of HCHO/intermediates with the Pt−CeO 2 interface domain. The catalyst with moderate bonding strength (i.e., Pt−Mn/CeO 2 ) displayed the highest reactivity under the ambient condition, while Pt−Cu/CeO 2 with the highest bonding strength showed a dramatically decreased activity. No correlation was observed between the abundancy of the active oxygen and catalytic activity, likely due to the oxygen supply having a much higher rate than the rate-determining step. This work contributes to the elucidation about the property−function relationship of a transitional metal dopant in Pt-based catalysts for the oxidation of HCHO.
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