Temperature-dependent orientation of self-organized nanopatterns on ion-irradiated TiO sub(2)(110)

Temperature-dependent self-organized formation of nanoripples on TiO sub(2)(110) surfaces irradiated by low-energy Ar super(+) beams has been investigated by scanning tunnelling microscopy in UHV conditions. Under the experimental conditions employed (2 keV Ar super(+) and oblique incidence, 75[degr...

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Bibliographic Details
Published in:Physical review. B, Condensed matter and materials physics Condensed matter and materials physics, 2013-11, Vol.88 (19)
Main Authors: Kolmer, M, Zebari, A A, Goryl, M, de Mongeot, F Buatier, Zasada, F, Piskorz, W, Pietrzyk, P, Sojka, Z, Krok, F, Szymonski, M
Format: Article
Language:English
Subjects:
Condensed matter
Diffusion
Formations
Irradiation
Nanostructure
Orientation
Titanium
Titanium dioxide
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Summary:Temperature-dependent self-organized formation of nanoripples on TiO sub(2)(110) surfaces irradiated by low-energy Ar super(+) beams has been investigated by scanning tunnelling microscopy in UHV conditions. Under the experimental conditions employed (2 keV Ar super(+) and oblique incidence, 75[degrees] off-normal, T = 120, 300, 620, and 720 K) on the irradiated surface the ripple structure of periodicity ~10 nm has developed. Interestingly, the orientation of the nanopatterns switches reversibly by 90[degrees] with the systematic change of the substrate temperature during irradiation. We have demonstrated that formation of the surface nanomorphology is determined by the interplay between the erosion of the monatomic step edges at grazing incidence, anisotropic surface diffusion along the favoured crystallographic orientation and, at elevated temperatures, the diffusion into the bulk of the excess Ti ions. As indicated by density functional theory (DFT) calculations used for modelling the diffusion processes on the ion irradiated TiO sub(2) (110), the significant surface mass transport required to form the nanoripples is dominated by the highly mobile Ti atoms diffusing in assistance of O adatoms.
ISSN:1098-0121
1550-235X