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Beilstein J. Nanotechnol. 2011, 2, 1–14, doi:10.3762/bjnano.2.1
Figure 1: Model of a binary oxide surface. Point defects such as color centers, which are preferably situated...
Figure 2: Experimental setup. a) Schematic of an Eigler-style bath cryostat. b) The walker unit is situated o...
Figure 3: The same tip senses both signals. (a–d) Pairs of simultaneously recorded signal curves from the fre...
Figure 4: Energetic levels. a) The Fermi levels of tip and sample when they are not electrically connected. b...
Figure 5: Magnesium oxide surface. a) Atomically resolved image recorded by NC-AFM. The position I and II ind...
Figure 6: Spectroscopy on point defects. a) NC-AFM image of 21 nm × 9 nm measured at a frequency shift of Δf ...
Figure 7: Dependence on tip-sample distance. Constant height line-scans across an F0 defect situated at a ste...
Figure 8: Dependence on tip-sample distance. a) Shift of the resonance frequency of a Pt0.9Ir0.1 tip on a reg...
Figure 9: Color centers on MgO. The left labeling assigns numbers to the defect types. The left graph shows t...
Figure 10: Atomic resolution NC-AFM image of a straight antiphase domain boundary (type I) in the aluminum oxi...
Figure 11: Height profiles. a) Cutout from Figure 10. White lines indicate positions where line profiles have been taken ...
Figure 12: Spectroscopy on aluminum oxide. a) STM image of a thin film of aluminum oxide on NiAl(110), 18 nm × ...