Morphology, electron structure, and catalytic activity in CO oxidation over a Au/FeO
x
/SiO2/Si(100) model
sample prepared by pulsed laser deposition (PLD) have been investigated by X-ray photoelectron spectroscopy
(XPS), UV photoelectron spectroscopy (UPS), and transmission electron microscopy (TEM). Two types of
sample were prepared denoted by PLD I and PLD II, the latter being prepared by multiple laser deposition
alternatively by iron and gold. PLD I was characterized in “as prepared” oxidized and reduced states, the
respective gold particle sizes being 3.8, 4.1, and 5 nm; the iron oxide support was amorphous after the first
two treatments while it was partially crystallized after reduction. The activity in CO oxidation increased after
oxidation of the sample, whereas it was diminished after subsequent reduction. XPS studies showed that
higher activity was associated with amorphous iron oxide with Fe 2p binding energy = 711.3 eV. It was
established that in developing the catalytic activity the gold should be metallic and the support should be
amorphous with high binding energy and the reaction occurs at the perimeter of gold particles. PLD II has
a slightly lower activity which might be the result of more crystalline phase in the iron oxide.
The surface morphology of machined screw-shaped titanium dental implants was modified by pulsed irradiation with an Nd glass laser. This method supplied very different surface elements in nanometer and micrometer ranges identified with scanning electron microscopy and atomic force microscopy as well. The surface composition was unchanged during these treatments. A rabbit experiment was carried out to investigate the direct bone contact (osseointegration) which was characterized by the removal torque of the implants. The 50 nm and 10-50 µm sized droplike elements were formed from the machined flat surface by the laser irradiation depending on the laser intensity. The osseointegration was enhanced by the increase of the density of nanosized elements and by the size of the microsized elements, showing the importance of this surface morphology in the direct bone-implant contact.
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