Tuning the Interaction between Platinum Single Atoms and Ceria by Zirconia Doping for Efficient Catalytic Ammonia Oxidation.

Aiming at the development of an efficient NH 3 oxidation catalyst to eliminate the harmful NH 3 slip from the stationary flue gas denitrification system and diesel exhaust aftertreatment system, a facile ZrO 2 doping strategy was proposed to construct Pt 1 /Ce x Zr 1- x O 2 catalysts with a tunable Pt-CeO 2 interaction strength and Pt-O-Ce coordination environment. According to the results of systematic characterizations, Pt species supported on Ce x Zr 1- x O 2 were mainly in the form of single atoms when x ≥ 0.7, and the strength of the Pt-CeO 2 interaction and the coordination number of Pt-O-Ce bond (CN Pt-O-Ce ) on Pt 1 /Ce x Zr 1- x O 2 showed a volcanic change as a function of the ZrO 2 doping amount. It was proposed that the balance between the reasonable concentration of oxygen defects and limited surface Zr-O x species well accounted for the strongest Pt-CeO 2 interaction and the highest CN Pt-O-Ce on Pt/Ce 0.9 Zr 0.1 O 2 . It was observed that the Pt/Ce 0.9 Zr 0.1 O 2 catalyst exhibited much higher NH 3 oxidation activity than other Pt/Ce x Zr 1- x O 2 catalysts. The mechanism study revealed that the Pt 1 species with the stronger Pt-CeO 2 interaction and higher CN Pt-O-Ce within Pt/Ce 0.9 Zr 0.1 O 2 could better activate NH 3 adsorbed on Lewis acid sites to react with O 2 thus resulting in superior NH 3 oxidation activity. This work provides a new approach for designing highly efficient Pt/CeO 2 based catalysts for low-temperature NH 3 oxidation.