posted on 2015-12-31, 00:00authored byM. Ahmadi, F. Behafarid, C. Holse, J. H. Nielsen, B. Roldan Cuenya
Colloidal
chemistry, in combination with nanoparticle (NP)/support
epitaxial interactions is used here to synthesize shape-selected and
thermodynamically stable metallic NPs over a broad range of NP sizes.
The morphology of three-dimensional palladium and platinum NPs supported
on TiO2(110) was investigated using scanning tunneling
microscopy. Well-defined Pd and Pt NPs were synthesized via inverse
micelle encapsulation. The initially spherical NPs were found to become
faceted and form an epitaxial relationship with the support after
high-temperature annealing (e.g., 1100 °C). Shape selection was
achieved for almost all Pd NPs, namely, a truncated octahedron shape
with (111) top and interfacial facets. The Pt NPs were however found
to adopt a variety of shapes. The epitaxial relationship of the NPs
with the support was evidenced by the alignment of the cluster’s
edges with TiO2(110)-[001] atomic rows and was found to
be responsible for the shape control. The ability of synthesizing
thermally stable shape-selected metal NPs demonstrated here is expected
to be of relevance for applications in the field of catalysis, since
the activity and selectivity of NP catalysts has been shown to strongly
depend on the NP shape.