CO adsorption on hydrogen saturated Ru(0001)

Riedmüller, B; Ciobica, IM Ionel; Papageorgopoulos, Dimitrios; Frechard, F G; Berenbak, B.; Kleyn, A.W.; Santen, van Ra Rutger

doi:10.1063/1.1395625

Cited by 23 publications

(25 citation statements)

References 41 publications

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“…Here it may be also noted that the detected CO amount does not increase significantly with larger subsequent CO exposures (beyond 37.5 L) when dosing at~100 K. It was demonstrated by Riedmüller et al that non-activated CO adsorption in a saturated H ad layer on Ru(0001) can only proceed at defects of the (1 1) H ad layer, such as coadsorbed CO molecules. [27,28] This process leads to the formation of small CO islands embedded in the H ad layer. [28] In contrast, adsorption of CO on a perfect (1 1) H ad layer is an activated process with a minimum activation barrier of~25 kJ mol…”

Section: Thermal Desorptionmentioning

confidence: 99%

“…[26,27] The integration of the TPD spectra shows that the possibility of CO adsorption on a D ad saturated surface leads to an extremely high total adsorbate coverage: 0.89 ML D ad + 0.19 ML CO ad [corresponding to 89 % of q D (Sat) + 28 % of q CO (Sat) for the two adsorbates on the surface alone]. In fact, a similar result is also observed for all other coadsorbed layers with smaller D ad pre-coverages (and consequently higher CO ad coverage).…”

mentioning

confidence: 98%

“…[26][27][28] Preferential adsorption of further CO molecules in the vicinity of already adsorbed CO molecules leads to the formation of small CO islands in the H ad layer. [28] Under the conditions of most studies, [25,29] the formation of segregated islands (of the two adsorbate species) seems to be the general case, although the encirclement of isolated CO molecules by subsequently adsorbed hydrogen was reported for small CO coverages at low temperatures ( 100 K).…”

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confidence: 99%

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Coadsorption of Hydrogen and CO on Hydrogen Pre‐Covered PtRu/Ru(0001) Surface Alloys

2010

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The influence of pre-adsorbed hydrogen on the adsorption of CO on well-defined PtRu/Ru(0001) surface alloys and the modification of the adsorption properties of both adsorbate species due to coadsorption was studied by a combination of temperature-programmed desorption and infrared spectroscopic measurements. The hydrogen binding strength is weakened both by surface alloy formation and by CO coadsorption. In the densely packed coadsorbate layers, which can be formed after CO post-adsorption, the adsorption properties of the adsorbed CO molecules are also affected significantly. Depending on the Pt surface concentration, the CO adsorption process on hydrogen pre-covered surfaces is blocked to a different extent with a decreasing blocking tendency for Pt-rich alloys.

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Section: Thermal Desorptionmentioning

confidence: 99%

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confidence: 98%

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confidence: 99%

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Coadsorption of Hydrogen and CO on Hydrogen Pre‐Covered PtRu/Ru(0001) Surface Alloys

2010

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“…[12,13] The present study follows up on our previous investigation of the dynamics of H 2 /D 2 dissociation on bare Ru(0001). [27] Herein, we probe the dynamics of D 2 dissociation on CO-covered Ru(0001).…”

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confidence: 99%

CO Blocking of D₂ Dissociative Adsorption on Ru(0001)

et al. 2008

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The influence of pre-adsorbed CO on the dissociative adsorption of D(2) on Ru(0001) is studied by molecular-beam techniques. We determine the initial dissociation probability of D(2) as a function of its kinetic energy for various CO pre-coverages between 0.00 and 0.67 monolayers (ML) at a surface temperature of 180 K. The results indicate that CO blocks D(2) dissociation and perturbs the local surface reactivity up to the nearest-neighbour Ru atoms. Non-activated sticking and dissociation become less important with increasing CO coverage, and vanish at theta(CO) approximately 0.33 ML. In addition, at high D(2) kinetic energy (>35 kJ mol(-1)) the site-blocking capability of CO decreases rapidly. These observations are attributed to a CO-induced activation barrier for D(2) dissociation in the vicinity of CO molecules.

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“…10,11 CO was found to displace and ultimately drive the H-atoms off the surface. In the process, stable CO-islands were formed in a "sea" of hydrogen.…”

Section: Introductionmentioning

confidence: 99%

Evidence of stable high-temperature Dx-CO intermediates on the Ru(0001) surface

Ueta

Groot

Juurlink

et al. 2012

The Journal of Chemical Physics

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We demonstrate the formation of complexes involving attractive interactions between D and CO on Ru(0001) that are stable at significantly higher temperatures than have previously been reported for such intermediate species on this surface. These complexes are evident by the appearance of new desorption features upon heating of the sample. They decompose in stages as the sample temperature is increased, with the most stable component desorbing at >500 K. The D:CO ratio remaining on the surface during the final stages of desorption tends towards 1:1. The new features are populated during normally incident molecular beam dosing of D 2 on to CO pre-covered Ru(0001) surfaces (180 K) when the CO coverage exceeds 50% of the saturation value. The amount of complex formed decreases somewhat with increasing CO pre-coverage. It is almost absent in the case of dosing on to the fully saturated surface. The results are interpreted in terms of both local and long-range rearrangements of the overlayer that give rise to the observed CO coverage dependence and limit the amount of complex that can be formed.

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CO adsorption on hydrogen saturated Ru(0001)

Cited by 23 publications

References 41 publications

Coadsorption of Hydrogen and CO on Hydrogen Pre‐Covered PtRu/Ru(0001) Surface Alloys

Coadsorption of Hydrogen and CO on Hydrogen Pre‐Covered PtRu/Ru(0001) Surface Alloys

CO Blocking of D₂ Dissociative Adsorption on Ru(0001)

Evidence of stable high-temperature Dx-CO intermediates on the Ru(0001) surface

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CO adsorption on hydrogen saturated Ru(0001)

Cited by 23 publications

References 41 publications

Coadsorption of Hydrogen and CO on Hydrogen Pre‐Covered PtRu/Ru(0001) Surface Alloys

Coadsorption of Hydrogen and CO on Hydrogen Pre‐Covered PtRu/Ru(0001) Surface Alloys

CO Blocking of D2 Dissociative Adsorption on Ru(0001)

Evidence of stable high-temperature Dx-CO intermediates on the Ru(0001) surface

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CO Blocking of D₂ Dissociative Adsorption on Ru(0001)