Hydroxylation Structure and Proton Transfer Reactivity at the Zinc Oxide-Water Interface
Abstract
The hydroxylation structural features of the first adsorption layer and its connection to proton transfer reactivity have been studied for the ZnO-liquid water interface at room temperature. Molecular dynamics simulations employing the ReaxFF forcefield were performed for water on seven ZnO surfaces with varying step concentrations. At higher water coverage a higher level of hydroxylation was found, in agreement with previous experimental results. We have also calculated the free energy barrier for transferring a proton to the surface, showing that stepped surfaces stabilize the hydroxylated state and decrease the water dissociation barrier. On highly stepped surfaces the barrier is only 2 kJ/mol or smaller. Outside the first adsorption layer no dissociation events were found during almost 100 ns of simulation time; this indicates that these reactions are much more likely if catalyzed by the metal oxide surface. Also, when exposed to a vacuum, the less stepped surfaces stabilize adsorption beyond monolayer coverage.
Additional Information
© 2011 American Chemical Society. Published In Issue May 05, 2011; Article ASAP April 12, 2011; Received: July 02, 2010; Revised: March 21, 2011. This work was supported by the Swedish Research Council (VR) and by NSF Grant #DMR 0427177. Computer time was provided by SNIC. The computations were performed on UPPMAX under Project s00707-54 and SweGRID under project 015/09-14. Useful discussions with professors Wim Briels (Twente University) and Philippe Bopp (Bordeaux University) are gratefully acknowledged.Additional details
- Eprint ID
- 23600
- DOI
- 10.1021/jp106144p
- Resolver ID
- CaltechAUTHORS:20110509-110054205
- Swedish Research Council
- DMR-0427177
- NSF
- Created
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2011-05-09Created from EPrint's datestamp field
- Updated
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2021-11-09Created from EPrint's last_modified field