Yinying Wei scite author profile

The role of bulk defects in the oxygen chemistry on reduced rutile TiO(2)(110)-(1 × 1) has been studied by means of temperature-programmed desorption spectroscopy and scanning tunneling microscopy measurements. Following O(2) adsorption at 130 K, the amount of O(2) desorbing at ∼410 K initially increased with increasing density of surface oxygen vacancies but decreased after further reduction of the TiO(2)(110) crystal. We explain these results by withdrawal of excess charge (Ti(3+)) from the TiO(2)(110) lattice to oxygen species on the surface and by a reaction of Ti interstitials with O adatoms upon heating. Important consequences for the understanding of the O(2)-TiO(2) interaction are discussed.

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Direct Evidence for Ethanol Dissociation on RutileTiO2(110)

Hansen

Huo

Martinez

et al. 2011

Phys. Rev. Lett.

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We have studied the interaction of ethanol with reduced TiO(2)(110)-(1 × 1) by high-resolution scanning tunneling microscopy (STM) measurements and density functional theory calculations. The STM data revealed direct evidence for the coexistence of molecularly and dissociatively adsorbed ethanol species on surface Ti sites. In addition, we found evidence for dissociation of ethanol at bridge-bonded O vacancies. The density functional theory calculations support these findings and rationalize the distinct diffusion behaviors of molecularly and dissociatively adsorbed ethanol species, as revealed in time-lapsed STM images.

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Unravelling Site-Specific Photo-Reactions of Ethanol on Rutile TiO2(110)

Hansen

Bebensee

Martinez

et al. 2016

Sci Rep

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Finding the active sites of catalysts and photo-catalysts is crucial for an improved fundamental understanding and the development of efficient catalytic systems. Here we have studied the photo-activated dehydrogenation of ethanol on reduced and oxidized rutile TiO2(110) in ultrahigh vacuum conditions. Utilizing scanning tunnelling microscopy, various spectroscopic techniques and theoretical calculations we found that the photo-reaction proceeds most efficiently when the reactants are adsorbed on regular Ti surface sites, whereas species that are strongly adsorbed at surface defects such as O vacancies and step edges show little reaction under reducing conditions. We propose that regular Ti surface sites are the most active sites in photo-reactions on TiO2.

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Flux-Selected Titanyl Phthalocyanine Monolayer Architecture on Ag (111)

2008

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The adsorption and molecular architecture of titanyl phthalocyanine (TiOPc) monolayer films on Ag (111) have been studied with scanning tunneling microscopy. Depending on deposition flux, TiOPc selectively forms three distinct ordered monolayer structures. At lower (<0.1 ML/min) fluxes, molecules assemble into a well-ordered (2 13 × 2 13)R13.9°honeycomb phase comprised of interlocked molecular pairs. This pairing effectively reduces the repulsion between the intrinsic molecular dipole and enhances the attraction between aromatic rings. At intermediate (0.2 ML/min) fluxes, molecules form a metastable ( 21 × 21)R10.9°h exagonal phase of uniformly tilted TiOPc. At higher (0.4 ML/min) fluxes, a misfit dislocation triangular network appears, consisting of uniformly sized TiOPc domains. Molecular models for the three distinct monolayer films are developed. We describe how local electrostatic intermolecular interactions stabilize kinetically accessible structures, driving phase selection.

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Yinying Wei

The Importance of Bulk Ti³⁺Defects in the Oxygen Chemistry on Titania Surfaces

Direct Evidence for Ethanol Dissociation on RutileTiO2(110)

Unravelling Site-Specific Photo-Reactions of Ethanol on Rutile TiO2(110)

Flux-Selected Titanyl Phthalocyanine Monolayer Architecture on Ag (111)

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About

Yinying Wei

The Importance of Bulk Ti3+Defects in the Oxygen Chemistry on Titania Surfaces

Direct Evidence for Ethanol Dissociation on RutileTiO2(110)

Unravelling Site-Specific Photo-Reactions of Ethanol on Rutile TiO2(110)

Flux-Selected Titanyl Phthalocyanine Monolayer Architecture on Ag (111)

Contact Info

Product

Resources

About

The Importance of Bulk Ti³⁺Defects in the Oxygen Chemistry on Titania Surfaces