Pd-Ce-O(x)/MWCNTs and Pt-Ce-O(x)/MWCNTs Composite Materials: Morphology, Microstructure, and Catalytic Properties

The composite nanomaterials based on noble metals, reducible oxides, and nanostructured carbon are considered to be perspective catalysts for many useful reactions. In the present work, multi-walled carbon nanotubes (MWCNTs) were used for the preparation of Pd-Ce-O(x)/MWCNTs and Pt-Ce-O(x)/MWCNTs catalysts comprising the active components (6 wt%Pd, 6 wt%Pt, 20 wt%CeO(2)) as highly dispersed nanoparticles, clusters, and single atoms. The application of X-ray diffraction (XRD) and high-resolution transmission electron microscopy (HRTEM) provided analysis of the samples’ morphology and structure at the atomic level. For Pd-Ce-O(x)/MWCNTs samples, the formation of PdO nanoparticles with an average crystallite size of ~8 nm was shown. Pt-Ce-O(x)/MWCNTs catalysts comprised single Pt(2+) ions and PtO(x) clusters less than 1 nm. A comparison of the catalytic properties of the samples showed higher activity of Pd-based catalysts in CO and CH(4) oxidation reactions in a low-temperature range (T(50) = 100 °C and T(50) = 295 °C, respectively). However, oxidative pretreatment of the samples resulted in a remarkable enhancement of CO oxidation activity of Pt-Ce-O(x)/MWCNTs catalyst at T < 20 °C (33% of CO conversion at T = 0 °C), while no changes were detected for the Pd-Ce-O(x)/MWCNTs sample. The revealed catalytic effect was discussed in terms of the capability of the Pt-Ce-O(x)/MWCNTs system to form unique PtO(x) clusters providing high catalytic activity in low-temperature CO oxidation.