Spin localization for NO adsorption on surface O atoms of metal oxides

Elucidating NO x Surface Chemistry at the Anatase (101) Surface in TiO2 Nanoparticles

Understanding NO _x chemistry at titania nanoparticle surfaces is important for photocatalytic environmental remediation processes. We focus on this problem and put forward an experimental-computational approach based on vibrational spectroscopy grounds. Temperature-dependent IR experiments of NO _x adsorption on shape-engineered nanoparticle (101) anatase surfaces are paired with power spectra obtained from Born-Oppenheimer trajectories. Then, the harmonic versus anharmonic vibrational frequencies of several adsorption scenarios are directly compared with the IR experiments. We conclude that molecules are adsorbed mainly by the N-end side and both the intermolecular interactions between adsorbed molecules and (NO)₂ dimer formation are responsible for the main NO adsorption spectroscopic features. We also investigate the spectroscopy and the mechanism of formation on defective anatase surfaces of the long-lived greenhouse gas N₂O.

The interplay between acid-base properties and Fermi level pinning of a nano dispersed tungsten oxide - titania catalytic system

A series of WO₃/TiO₂ catalysts were synthesized, characterized, and evaluated for the NO selective catalytic reduction (SCR) with NH₃. Based on a wide range of characterization techniques, a detailed model was developed that describes the interfacial electron transfer between WO₃ and TiO₂ and defines a relationship between the acid-base properties of the catalytic surface and electronic structure modification. The electronic interactions at the WO₃/TiO₂ interface were quantified using variations in the system's electronic structure. Altering the dispersion and size of the WO₃ nanostructures results to drastic changes in titania's surface electron distribution, which are reflected in the pinning of Fermi level through an electron transfer process between WO₃ and TiO₂. The variations in the Fermi level were further related to changes in the point of zero charge (PZC) values and the activity towards NO SCR with NH_3, which was used as a test reaction. Temperature Programmed Surface Reaction (TPSR) was employed to study the catalytic activity at temperatures ranging from 30 °C to 500 °C and was quantitatively correlated to changes in coverage and interfacial charge transfer. We demonstrate that higher WO₃ loading on TiO₂ results in a stronger electronic interaction and a higher catalytic activity. This is because electron transfer increases the surface electron density, which enhances the surface basicity of TiO₂. The concomitant decrease in the adsorption energy of NH₃ results in a decrease in the activation energy, which is reflected in the SCR temperature onset.