Electron transferring with oxygen defects on Ni-promoted Pd/AlO catalysts for low-temperature lean methane combustion.

Methane (CH) is the second most consequential greenhouse gas after CO, with a substantial global warming potential. The CH catalytic combustion offers an efficient method for the elimination of CH. However, improving the catalytic performance of Pd-based materials for low-temperature CH combustion remains a big challenge. In this study, we synthesized an enhanced Pd/5NiAlO catalyst that demonstrated superior catalytic activity and improved water resistance compared to the Pd/AlO catalyst. Specifically, the T was decreased by over 100 °C under both dry and wet conditions. Introducing Ni resulted in an enormously enhanced number of oxygen defects on the obtained 5NiAlO support. This defect-rich support facilitates the anchoring of PdO through increased electron transfer, thereby inhibiting the production of high-valence Pd and stimulating the generation of unsaturated Pd sites. Pd can effectively activate surface oxygen and PdO plays a significant role in activating CH, resulting in high activity for Pd/5NiAlO. On the other hand, the increased water resistance of Pd/5NiAlO was mainly due to the generation of *OOH species and the lower accumulation of surface -OH species during the reaction process.