Dissociation of water on atomically-defined cobalt oxide nanoislands on Pt(111) and its effect on the adsorption of CO

We have investigated the adsorption and dissociation of water and its co-adsorption with CO on atomically defined cobalt oxide nanoislands on Pt(111). The CoO islands were prepared under ultrahigh vacuum (UHV) conditions by reactive deposition of Co metal in oxygen atmosphere. The island structure w...

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Published inJournal of materials research Vol. 34; no. 3; pp. 379 - 393
Main Authors Wähler, Tobias, Hohner, Chantal, Sun, Zhaozong, Schuster, Ralf, Rodríguez-Fernández, Jonathan, Lauritsen, Jeppe Vang, Libuda, Jörg
Format Journal Article
LanguageEnglish
Published New York, USA Cambridge University Press 14.02.2019
Springer International Publishing
Springer Nature B.V
Subjects
Adsorption
Applied and Technical Physics
Bilayers
Biomaterials
Cobalt
Cobalt oxides
Electrocatalysis
Electrons
Hydroxyl groups
Hydroxylation
Infrared reflection
Inorganic Chemistry
Invited Article
Islands
Materials Engineering
Materials research
Materials Science
Metal oxides
Morphology
Nanotechnology
Single crystals
Spectrum analysis
Studies
Terraces
Ultrahigh vacuum
Water chemistry
infrared (IR) spectroscopy
oxide
scanning tunneling microscopy (STM)
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Summary:We have investigated the adsorption and dissociation of water and its co-adsorption with CO on atomically defined cobalt oxide nanoislands on Pt(111). The CoO islands were prepared under ultrahigh vacuum (UHV) conditions by reactive deposition of Co metal in oxygen atmosphere. The island structure was characterized by scanning tunneling microscopy (STM), showing that the nanoislands consist of a CoO bilayer and are regularly shaped with island edges that are mainly terminated by Co2+ ions. D2O was dosed in UHV onto the CoO islands on Pt(111) after pre-saturation with CO. D2O dissociation was monitored in situ by isothermal and temperature programmed infrared reflection absorption spectroscopy (IRAS). Isotopic exchange experiments were performed with H2O, D2O, and D218O to elucidate the nature of the hydroxyl groups. Three principal types of OD species are identified: (i) isolated OD at the edges of the CoO islands (Co-OeD), (ii) OD groups within larger hydroxylated areas on the CoO islands (Co-OcD), and (iii) isolated OD groups on the CoO terraces (Co-OtD). At 400 K, water adsorbs dissociatively on the CoO islands and forms isolated hydroxyl species (Co-OeD) at the island edges only. At room temperature (300 K), the coverage of hydroxyl groups increases rapidly, in line with the water-assisted hydroxylation reaction suggested previously. Adsorption experiments with D218O suggest that two equivalent groups are formed from one water molecule after dissociation at island edges, leading to the formation of larger hydroxylated areas on the CoO islands (Co-OcD) and, in addition, isolated OD species on the CoO terraces (Co-OtD). While the initial step of D2O dissociation is facile, the formation of larger hydroxylated areas is a slow and irreversible process. At 200 K, the formation of hydroxylated areas is accompanied by the co-adsorption of molecular water. The hydroxyl groups on the CoO islands are shown to interact with the CO preadsorbed on the CoO/Pt(111) model system. In particular, we observe a new CO species, stabilized by OD groups on the CoO islands, which adsorbs much stronger than CO on the OD-free CoO surface.
ISSN:0884-2914
2044-5326
DOI:10.1557/jmr.2018.388