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Imaging oxide film

As we have seen in the previous chapter, the apparent topography and corrugation of thin oxide films as imaged by STM may vary drastically as a function of the sample bias. This will of course play an important role in the determination of cluster sizes with STM, which will be discussed in the following section. The determination of the size of the metallic nanoparticles on oxide films is a crucial issue in the investigation of model catalysts since the reactivity of the particles may be closely related to their size. Therefore, the investigation of reactions on model catalysts calls for a precise determination of the particle size. If the sizes of the metal particles on an oxidic support are measured by STM, two different effects, which distort the size measurement, have to be taken into account. [Pg.39]

Although oxides are generally considered to be insulators, it is sometimes possible to monitor the surface of an oxide film by STM. Basically two mechanisms that explain the imaging of oxide surfaces by in situ STM are considered ... [Pg.271]

Fig. 10.1.7 High-resolution TEM image of the carbon tubes from the anodic oxide film with 30-nm channels with a carbon deposition period of 6 h. (From Ref. 12.)... Fig. 10.1.7 High-resolution TEM image of the carbon tubes from the anodic oxide film with 30-nm channels with a carbon deposition period of 6 h. (From Ref. 12.)...
In comparison to most other methods in surface science, STM offers two important advantages (1) it provides local information on the atomic scale and (2) it does so in situ [50]. As STM operates best on flat surfaces, applications of the technique in catalysis relate to models for catalysts, with the emphasis on metal single crystals. Several reviews have provided excellent overviews of the possibilities [51-54], and many studies of particles on model supports have been reported, such as graphite-supported Pt [55] and Pd [56] model catalysts. In the latter case, Humbert et al. [56] were able to recognize surface facets with (111) structure on palladium particles of 1.5 nm diameter, on an STM image taken in air. The use of ultra-thin oxide films, such as AI2O3 on a NiAl alloy, has enabled STM studies of oxide-supported metal particles to be performed, as reviewed by Freund [57]. [Pg.208]

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Oxidation films

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