Structure-Activity Correlations for the Oxidation of CO over Polycrystalline RuO<sub>2</sub> Powder Derived from Steady-State and Transient Kinetic Experiments

Narkhede, Vijay; Aßmann, J.

doi:10.1524/zpch.219.7.979.67092

Cited by 31 publications

(65 citation statements)

References 20 publications

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“…It was evidenced by the evolution of the Ru 3d and O 1s spectra, which was terminated at the formation of 'surface oxide'. The CO 2 yield grew steadily showing stable activity at constant temperature until levelling off at around 500 K and declining slowly above 550 K. This result is qualitative agreement with the results with powdered Ru catalyst which demonstrate that an ultra-thin oxide layer covering the metallic Ru core is the active state in CO oxidation at temperatures below 500 K [33].…”

Section: Figuresupporting

confidence: 89%

“…The longrange ordering of the RuO 2 (110) surface is not prerequisite for catalytic function but was instrument to unravel and theoretically understand mechanisms of CO oxidation at the atomic level. As noted above, very recent study of the CO oxidation on polycrystalline powdered Ru catalyst in the temperature range 363-453 K showed that under dynamic catalytic conditions the active state are the ultra-thin Ru oxide films, whereas fully oxidized RuO 2 particles, formed at higher temperature, exhibit lower activity [33]. This deactivation is tentatively attributed to roughening and formation of inactive RuO 2 facets.…”

Section: Discussionmentioning

confidence: 82%

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Catalytically active states of Ru(0001) catalyst in CO oxidation reaction

Blume

Hävecker

Zafeiratos

et al. 2006

Journal of Catalysis

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Identifying the composition of the catalytically active state of metal catalysts under dynamic operating conditions is of particular importance for oxidation catalysis. We report here new insights into the chemical identity of different catalytically active states formed on a Ru(0001) catalyst during the CO oxidation at different reaction temperatures. The changes in the surface composition of the Ru catalyst and the CO 2 yield under varying reaction conditions in the 10 -4 to 10 -1 mbar pressure range were followed in-situ by synchrotron-based high-pressure x-ray photoelectron spectroscopy and mass spectroscopy. The obtained results reveal that the catalytic activity of a few layers thick 'surface oxide' without well defined stoichiometry and structure is comparable with the activity of the stoichiometric RuO 2 (110) phase. The 'surface oxide' forms under reaction conditions when the formation of the RuO 2 is kinetically hindered, and can coexist with RuO 2 in a wide temperature-pressure range.

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Section: Figuresupporting

confidence: 89%

Section: Discussionmentioning

confidence: 82%

Catalytically active states of Ru(0001) catalyst in CO oxidation reaction

Blume

Hävecker

Zafeiratos

et al. 2006

Journal of Catalysis

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“…The occurrence of this reconstructed RuO 2 (100)-c(2 × 2) surface is nicely supported by our experiments: First, the irregular octagonal cross section habit of the calcined RuO 2 crystals in contrast to the obelisk-like habit shown in the literature [24] points to an equilibration of the (110) and (100) surface energies. This would be the case for a RuO 2 (100)-c(2 × 2) microfacetted (110) surface.…”

Section: Ruo 2 As Bulk Phasesupporting

confidence: 87%

“…The same argument holds for the immediate activity of polycrystalline pre-calcined RuO 2 in Narkhede et al [24] because they used a low precalcination temperature of 573 K. Since our very long induction times are not reported in the literature we will discuss them in the context of deactivation.…”

Section: Ruo 2 As Bulk Phasementioning

confidence: 52%

“…Since it is obviously very ambiguous, if not impossible, to grow solely one single surface oxygen-phase on Ru(0001) except for RuO 2 at very high temperatures and oxygen dosages, it is interesting to analyze catalytic experiments with fully oxidized RuO 2 . Several papers dealt with re-oxidized Ru particles as "core-shell" catalysts with a thin RuO 2 layer on a Ru metal core [10,24,25]. These catalysts should exhibit the highest formation rates of CO 2 [10].…”

Section: Surface State Of the Catalystmentioning

confidence: 99%

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On the CO-Oxidation over Oxygenated Ruthenium

Rosenthal¹,

Girgsdies

Timpe

et al. 2009

Zeitschrift Für Physikalische Chemie

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The oxidation of carbon monoxide over polycrystalline ruthenium dioxide (RuO 2 ) powder was studied in a packed-bed reactor and by bulk and surface analytical methods. Activity data were correlated with bulk phases in an in-situ X-ray diffraction (XRD) setup at atmospheric pressure. Ruthenium dioxide was pre-calcined in pure oxygen at 1073 K. At this stage RuO 2 is completely inactive in the oxidation of CO. After a long induction period in the feed at 503 K RuO 2 becomes active with 100% conversion, while in-situ XRD reveals no changes in the RuO 2 diffraction pattern. At this stage selective roughening of apical RuO 2 facets was observed by scanning electron microscopy (SEM). Seldom also single lateral facets are roughened. EDX indicated higher oxygen content in the following order: flat lateral facets > rough lateral facets > rough apical facets. Further, experiments in the packed bed reactor indicated oscillations in the CO 2 formation rate. At even higher temperatures in reducing feed (533-543 K) the sample reduces to ruthenium metal according to XRD. The reduced particles exhibiting lower ignition temperature are very rough with cracks and deep star-shaped holes. An Arrhenius plot of the CO 2 formation rate below the ignition temperature reveals the reduced samples to be significantly more active based on mass unit and shows lower apparent activation energy than the activated oxidized sample. Micro-spot X-ray photoelectron spectroscopy (XPS) and XPS microscopy experiments were carried out on a Ru(0001) single crystal exposed to oxygen at different temperature. Although low energy electron diffraction (LEED) images show a strong 1x1 pattern, the XPS data indicated a wide lateral inhomogeneity with different degree of oxygen dissolved in the subsurface layers. All these and the literature data are discussed in the context of different active states and transport issues, and the metastable nature of a phase mixture under conditions of high catalytic activity.

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