Stefan Wendt scite author profile

Titanium dioxide (TiO 2 ) has a number of uses in catalysis, photochemistry, and sensing that are linked to the reducibility of the oxide. Usually, bridging oxygen (O br ) vacancies are assumed to cause the Ti 3d defect state in the band gap of rutile TiO 2 (110). From high-resolution scanning tunneling microscopy and photoelectron spectroscopy measurements, we propose that Ti interstitials in the near-surface region may be largely responsible for the defect state in the band gap. We argue that these donor-specific sites play a key role in and may dictate the ensuing surface chemistry, such as providing the electronic charge required for O 2 adsorption and dissociation. Specifically, we identified a second O 2 dissociation channel that occurs within the Ti troughs in addition to the O 2 dissociation channel in O br vacancies. Comprehensive density functional theory calculations support these experimental observations.

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Atomic-Scale Structure and Catalytic Reactivity of the RuO₂(110) Surface

Over

Kim

Seitsonen

et al. 2000

Science

873

726

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The structure of RuO(2)(110) and the mechanism for catalytic carbon monoxide oxidation on this surface were studied by low-energy electron diffraction, scanning tunneling microscopy, and density-functional calculations. The RuO(2)(110) surface exposes bridging oxygen atoms and ruthenium atoms not capped by oxygen. The latter act as coordinatively unsaturated sites-a hypothesis introduced long ago to account for the catalytic activity of oxide surfaces-onto which carbon monoxide can chemisorb and from where it can react with neighboring lattice-oxygen to carbon dioxide. Under steady-state conditions, the consumed lattice-oxygen is continuously restored by oxygen uptake from the gas phase. The results provide atomic-scale verification of a general mechanism originally proposed by Mars and van Krevelen in 1954 and are likely to be of general relevance for the mechanism of catalytic reactions at oxide surfaces.

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Oxygen vacancies on TiO2(110) and their interaction with H2O and O2: A combined high-resolution STM and DFT study

et al. 2005

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Enhanced Bonding of Gold Nanoparticles on Oxidized TiO ₂ (110)

Matthey

Wang

Wendt

et al. 2007

Science

473

509

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We studied the nucleation of gold clusters on TiO2(110) surfaces in three different oxidation states by high-resolution scanning tunneling microscopy. The three TiO2(110) supports chosen were (i) reduced (having bridging oxygen vacancies), (ii) hydrated (having bridging hydroxyl groups), and (iii) oxidized (having oxygen adatoms). At room temperature, gold nanoclusters nucleate homogeneously on the terraces of the reduced and oxidized supports, whereas on the hydrated TiO2(110) surface, clusters form preferentially at the step edges. From interplay with density functional theory calculations, we identified two different gold-TiO2(110) adhesion mechanisms for the reduced and oxidized supports. The adhesion of gold clusters is strongest on the oxidized support, and the implications of this finding for catalytic applications are discussed.

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Stefan Wendt

The Role of Interstitial Sites in the Ti 3d Defect State in the Band Gap of Titania

Atomic-Scale Structure and Catalytic Reactivity of the RuO₂(110) Surface

Oxygen vacancies on TiO2(110) and their interaction with H2O and O2: A combined high-resolution STM and DFT study

Enhanced Bonding of Gold Nanoparticles on Oxidized TiO ₂ (110)

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Stefan Wendt

The Role of Interstitial Sites in the Ti 3d Defect State in the Band Gap of Titania

Atomic-Scale Structure and Catalytic Reactivity of the RuO2(110) Surface

Oxygen vacancies on TiO2(110) and their interaction with H2O and O2: A combined high-resolution STM and DFT study

Enhanced Bonding of Gold Nanoparticles on Oxidized TiO 2 (110)

Contact Info

Product

Resources

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Atomic-Scale Structure and Catalytic Reactivity of the RuO₂(110) Surface

Enhanced Bonding of Gold Nanoparticles on Oxidized TiO ₂ (110)