About

Log in?

DTU users get better search results including licensed content and discounts on order fees.

Anyone can log in and get personalized features such as favorites, tags and feeds.

Log in as DTU user Log in as non-DTU user No thanks

DTU Findit
Boolean: (bicycle AND helmet) OR (head AND protection) (always group AND in parenthesis)
Title: title:(climate change)
Author: author:("bohr niels" OR "bohr n") (avoid only full first name)
Phrase: "water pump control" (does not work with wildcards)
Wildcards: wom?n pharm*

More help on how to search

Flexible matching

About search syntax

Search syntax Advanced
Close advanced
{{problem}}
By field Using AND/OR By author
This tool can help you build boolean queries suitable for doing a broad search for different synonyms or spellings of each word. Start via the drop-down below or just start typing in the search field.
{{ row.typeTitle }}: ( )

Since our index often lack the full first name of people it can be difficult to correctly search by author.

Fill in the fields and let us help you build a good query:

If you need to find everything possible, consider only searching by last name.

Use "Starting year" to ignore publications out of year range.

More...

Journal article

Oxygen vacancies as active sites for water dissociation on rutile TiO2(110)

By Schaub, R.1; Thostrup, P.1; Lopez, Nuria2; Lægsgaard, E.1; Stensgaard, I.1; Nørskov, Jens Kehlet2,3; Besenbacher, Flemming2

From

Aarhus University1

Department of Physics, Technical University of Denmark2

Computational Atomic-scale Materials Design, Department of Physics, Technical University of Denmark3

Through an interplay between scanning tunneling microscopy experiments and density functional theory calculations, we determine unambiguously the active surface site responsible for the dissociation of water molecules adsorbed on rutile TiO2(110). Oxygen vacancies in the surface layer are shown to dissociate H2O through the transfer of one proton to a nearby oxygen atom, forming two hydroxyl groups for every vacancy.

The amount of water dissociation is limited by the density of oxygen vacancies present on the clean surface exclusively. The dissociation process sets in as soon as molecular water is able to diffuse to the active site.

Language: English
Year: 2001
Pages: 266104
ISSN: 00319007 and 10797114
Types: Journal article
DOI: 10.1103/PhysRevLett.87.266104
ORCIDs: Nørskov, Jens Kehlet

DTU users get better search results including licensed content and discounts on order fees.

Log in as DTU user

Access

Analysis