A PdO/CeO composite with a rod-like nanoporous skeletal structure was prepared by combining the dealloying of Al-Ce-Pd alloy ribbons with calcination. For CO oxidation and CH combustion, the nanoporous PdO/CeO composite exhibits excellent catalytic activity, and the complete reaction temperatures of CO and CH are 80 °C and 380 °C, respectively. In addition, the composite possesses excellent cycle stability, CO toxicity, and water resistance, and the catalytic activity hardly decreases after 100 h of long-term stability testing in the presence of water vapour (2 × 10 ppm). The results of a series of characterizations indicate that the enhanced catalytic activity can be attributed to the good dispersion of the PdO nanoparticles, large specific surface area, strong redox capacity, interaction between PdO and CeO, and more surface active oxygen on PdO. The results of the characterization and experiments also indicate that the PdO nanoparticles, prepared by combining dealloying and calcination, have a stronger catalytic activity than do Pd nanoparticles. Finally, a simple model is used to summarize the catalytic mechanism of the PdO/CeO composite. It is hoped that this work will provide insights into the development of high-activity catalysts.
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| http://dx.doi.org/10.1186/s11671-019-3029-4 | DOI Listing |
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