Abstract
Porosity in functional oxide nanorods is a recently discovered new type of microstructure, which is not yet fully understood and still under evaluation for its impact on applications in catalysis and gas/ion storage. Here we explore the shape and distribution of pores in ceria in three dimensions using a modified algorithm of geometric tomography as a reliable tool for reconstructing defective and strained nanoobjects. The pores are confirmed as “negative-particle” or “inverse-particle” cuboctahedral shapes located exclusively beneath the flat surface of the rods separated via a sub-5 nm thin ceria wall from the outside. New findings also comprise elongated “negative-rod” defects, seen as embryonic nanotubes, and pores in cube-shaped ceria. Furthermore, we report near-sintering secondary heat treatment of nanorods and cubes, confirming persistence of pores beyond external surface rounding. We support our experiments with molecular modeling and predict that the growth history of voids is via diffusion and aggregation of atomic point defects. In addition, we use density functional theory to show that the relative stability of pore (shape) increases in the order “cuboidal” < “hexagonal-prismatic” < “octahedral”. The results indicate that by engineering voids into nanorods, via a high-temperature postsynthetic heat treatment, a potential future alternative route of tuning catalytic activities might become possible.
Highlights
Ceria has remained one of the most studied nanostructured materials for many decades.[1]
We introduce a modified version of geometric tomography[32−34] applied to electron tomography of crystalline materials with nonconvex features, not normally eligible for this technique
Postsynthesis heat treatment was mostly conducted by conventional furnace heating of powders; we added to the procedure some heat treatment of small powder samples suspended on Si/Si3N4 TEM carrier films, annealed in air with a heating rate of 5 °C/min, held at 800 °C
Summary
Ceria has remained one of the most studied nanostructured materials for many decades.[1] Its abundance and versatility have seen its impact increase steadily. Since 2014, over half of the publications on nanoceria have concerned uses in catalysis.[2] cutting-edge applications can be found across many other disciplines from biomedical[3] to energy and environmental[4,5] processes. The high redox activity and structural stability of ceria-based materials make them appealing for the ever-growing field of heterogeneous catalysis, where novel structures are constantly being developed and tested for their catalytic performance.[6] Rod-shaped nanoparticles are of particular interest, as they present higher activity than other ceria nanostructures of similar surface area.[7−9] This is attributed to the presence of exposed planes and to the number of {100} and {110} surfaces
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