CO Oxidation Reaction over Oxygen-Rich Ru(0001) Surfaces

Böttcher, Artur; Niehus, Horst; Schwegmann, S.; Over, Herbert; Ertl, G.

doi:10.1021/jp9726899

Cited by 157 publications

(182 citation statements)

References 31 publications

(36 reference statements)

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“…S2), suggesting that this sample contains also some silica nanoparticles. The sample was then treated with 16 O 2 , and the TPD spectrum was recorded. The results revealed desorption exclusively of 16 O 2 (Fig.…”

Section: Pure Silicate Filmsmentioning

confidence: 99%

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

et al. 2016

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Abstract. Bilayer silicate films grown on metal substrates are weakly bound to the metal surfaces, which allows ambient gas molecules to intercalate the oxide/metal interface. In this work, we studied the interaction of oxygen with Ru(0001) supported ultrathin silicate and aluminosilicate films at elevated O 2 pressures (10 -5 -10 mbar) and temperatures (450 -923 K). The results show that the silicate films stay essentially intact under these conditions, and oxygen in the film does not readily exchange with oxygen in the ambient. O 2 molecules readily penetrate the film and dissociate on the underlying Ru surface underneath. The silicate layer does however strongly passivate the Ru surface towards RuO 2 (110) oxide formation that readily occurs on bare Ru(0001) under the same conditions. The results indicate considerable spatial effects for oxidation reactions on metal surfaces in the confined space at the interface. Moreover, the aluminosilicate films completely suppress the Ru oxidation, providing some rationale for using crystalline aluminosilicates in anti-corrosion coatings.

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Section: Pure Silicate Filmsmentioning

confidence: 99%

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

et al. 2016

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“…The formation of crystalline, bulk-like RuO 2 (110) during high-pressure CO oxidation catalysis has indeed been observed experimentally at Ru(0001), but it is interesting to note that even after long operation times the film thicknesses never exceeded about 20Å 30,31,52 . Generally, one could interpret this finding as reflecting kinetic limitations to a continued growth, presumably due to slow diffusion of either O or Ru atoms through the formed film.…”

Section: Kinetically Limited Film Thicknessmentioning

confidence: 70%

“…Recent experimental studies seem to support this view, i.e., they indicate that thin oxidic structures, now mostly coined surface oxides, start to form roughly at coverages Θ c . 30,31,32,33,34 For the "true" bulk oxide a higher oxygen concentra- tion might be required, but for oxide nucleation and for the formation of oxidic islands such increased oxygen content is only needed locally. In this respect it is remarkable that although for the on-surface adsorption at the late 4d TM basal surface the adatom-adatom interaction is repulsive (see the discussion of Fig.…”

Section: Oxygen Accumulation In the Surface Region And Surface Oximentioning

confidence: 99%

“…2 conform much better with the widespread use of these metals in catalytic car converters, whereas the oxygen bonding at Ru(0001) seems simply too strong. The correspondingly somehow enigmatic high catalytic activity of Ru(0001) at ambient pressures only became comprehensible when experimental studies reported the formation of bulk-like RuO 2 (110) films at the surface in such reactive environments 30,31 . The subsequently established 62 and above described high activity of this oxide surface then not only explained the pressure gap difference (Ru metal in UHV = low activity, RuO 2 at high-pressures = high activity), but also reconciled this system with the Sabatier principle: The RuO 2 (110) surface indeed features oxygen species that are bound with intermediate bond strength comparable to the one of O at Rh(111) and Pd(111).…”

Section: E Surface Oxidation and Sabatier Principlementioning

confidence: 99%

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Nanometer and Subnanometer Thin Oxide Films at Surfaces of Late Transition Metals

Reuter

2007

Nanocatalysis

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If metal surfaces are exposed to sufficiently oxygen-rich environments, oxides start to form. Important steps in this process are the dissociative adsorption of oxygen at the surface, the incorporation of O atoms into the surface, the formation of a thin oxidic overlayer and the growth of the once formed oxide film. For the oxidation process of late transition metals (TM), recent experimental and theoretical studies provided a quite intriguing atomic-scale insight: The formed initial oxidic overlayers are not merely few atomic-layer thin versions of the known bulk oxides, but can exhibit structural and electronic properties that are quite distinct to the surfaces of both the corresponding bulk metals and bulk oxides. If such nanometer or even sub-nanometer surface oxide films are stabilized in applications, new functionalities not scalable from the known bulk materials could correspondingly arise. This can be particularly important for oxidation catalysis, where technologically relevant gas phase conditions are typically quite oxygen-rich. In such environments surface oxides may even form naturally in the induction period, and actuate then the reactive steady-state behavior that has traditionally been ascribed to the metal substrates. Corresponding aspects are reviewed by focusing on recent progress in the modeling and understanding of the oxidation behavior of late TMs, using particularly the late 4d series from Ru to Ag to discuss trends.

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“…It is in analogy to RuO 2 growth on Ru(0001) substrate prepared at temperature 530 o C by insitu sputtering [35], where RuO 2 film exhibits mixed (110) and (100) orientations, but the (100)-orientation is dominant, revealing that RuO 2 grows also in favor of (100) orientation on Ru(0001) in the gas phase conditions [35]. However, a well-ordered (110) RuO 2 film on Ru(0001) has been obtained by gas phase oxidation at a sample temperature of 700 K under UHV conditions [36]. The same RuO 2 film (110) oriented on MgO(100) has been observed by metal-organic vapor deposition at deposition temperature of 350 o C [37], while RuO 2 film (100) oriented on LaAlO 3 has been prepared at deposition temperature of 600 o C [38].…”

Section: Epitaxial Growth Of Ruthenium Dioxides On Ru(0001) Surfacementioning

confidence: 99%

Epitaxial Growth of Ruthenium Dioxides on Ru(0001) Surface

Nien¹,

Zei²

2016

NanoWorld J

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CO Oxidation Reaction over Oxygen-Rich Ru(0001) Surfaces

Cited by 157 publications

References 31 publications

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

Nanometer and Subnanometer Thin Oxide Films at Surfaces of Late Transition Metals

Epitaxial Growth of Ruthenium Dioxides on Ru(0001) Surface

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