Atomic resolution scanning tunneling microscopy (STM), noncontact atomic force microscopy (NC-AFM),
X-ray photoemission spectroscopy (XPS), low-energy electron diffraction (LEED), and formic acid adsorption
experiments were used to characterize the (001) surface of anatase TiO2. A combination of NC-AFM and
STM imaging was used to distinguish features due to geometrical and electronic effects. The contrast in
images of the bare (1 × 4) surface and the formate-covered surface is dominated by the surface topography
in both NC-AFM and STM, although electronic effects in the troughs contribute features to the STM images
that are absent from NC-AFM images. High-resolution imaging by STM and NC-AFM revealed that the
highest point of the ridge of the (1 × 4) structure consists of a single row of atoms. Formate adsorbs at
under-coordinated Ti sites in the added rows with a minimum separation of 2a
0 and never adsorbs in the
trenches even though the trenches also likely expose under-coordinated Ti atoms. The sticking probability of
formate on the anatase TiO2(001)−(1 × 4) surface is near unity initially, and falls dramatically once the
saturation coverage of 1/8 ML is reached. We show that of the current models for the (1 × 4) reconstruction,
an added row plus surface oxygen vacancy model and the recently proposed add-molecule model are in best
agreement with all of the data.
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