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Acetone and Water on TiO₂ (110): Competition for Sites

Journal Article · · Langmuir
DOI:https://doi.org/10.1021/la0476579· OSTI ID:15020588

The competitive interaction between acetone and water for surface sites on TiO? (110) was examined using temperature programmed desorption (TPD). Two surface pretreatment methods were employed, one involving vacuum reduction of the surface by annealing at 850 K in ultrahigh vacuum (UHV) and another involving surface oxidation with molecular oxygen. In the former case the surface possessed about 7% oxygen vacancy sites and in the latter reactive oxygen species (adatoms and molecules) were deposited on the surface as a result of oxidative filling of vacancy sites. On the reduced surface, excess water displaced all but about 20% of a saturated d6-acetone first layer to physisorbed desorption states, whereas about 40% of the first layer d6-acetone was stabilized on the oxidized surface against displacement by water through a reaction between oxygen and d6-acetone. The displacement of acetone on both surface is explained in terms of the relative desorption energies of each molecule on the clean surface and role of intermolecular repulsions in shifting their respective desorption features to lower temperatures with increasing coverage. Although first layer water desorbs from TiO? (110) at slightly lower temperature (275 K) than submonolayer coverages of d6-acetone (340 K), intermolecular repulsions between d6-acetone molecules shift its leading edge for desorption to 170 K as the first layer is saturated In contrast, the desorption leading edge for first layer water (with or without coadsorbed d6-acetone) was at 210 K. This small difference in the onsets for d6-acetone and water desorption resulted in the majority of d6-acetone being compressed into islands by water and eventually displaced from the first layer when excess water was adsorbed. On the oxidized surface the species resulting from reaction of d6-acetone and oxygen was not influence by increasing water coverages. This species was stable on the clean surface up to 375 K (well past the first layer water TPD feature) where it decomposed mostly back to d6-acetone and atomic oxygen. These results are discussed in terms of the influence of water in inhibiting acetone photo-oxidation on TiO? surfaces.

Research Organization:
Pacific Northwest National Laboratory (PNNL), Richland, WA (US), Environmental Molecular Sciences Laboratory (EMSL)
Sponsoring Organization:
USDOE
DOE Contract Number:
AC05-76RL01830
OSTI ID:
15020588
Report Number(s):
PNNL-SA-42844; 11105; KC0201050
Journal Information:
Langmuir, Journal Name: Langmuir Journal Issue: 8 Vol. 21; ISSN LANGD5; ISSN 0743-7463
Country of Publication:
United States
Language:
English

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Related Subjects

37 INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
ACETONE
Environmental Molecular Sciences Laboratory
SORPTION
SURFACE PROPERTIES
SURFACE TREATMENTS
TITANIUM OXIDES
TiO₂(110)
WATER
acetone
surface chemistry
water