Dissociative hydrogen adsorption on palladium requires aggregates of three or more vacancies

Mitsui, Toshiyuki; Rose, M.; Фомин, Э. В.; Ogletree, D. Frank; Salmerón, Miquel

doi:10.1038/nature01557

Cited by 301 publications

(255 citation statements)

References 8 publications

(14 reference statements)

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“…The experimental measurements [1] at 65 K show that on the 3V ensembles the hydrogen sticking coefficient s is more than 50 times larger than on the 2V ones. The present model gives a reactivity of H-free trimers centered on top positions to be about 10 9 times higher than that of the 2V ensembles, and 10 6 times higher than that of the 3V H ones, and thus explains the experimental observations.…”

Section: H Y S I C a L R E V I E W L E T T E R S Week Ending 1 Octobementioning

confidence: 99%

“…In order to adsorb on such a surface the reactant molecules must find empty surface sites (active sites) created either by one missing adsorbate (vacancy) or by aggregates (ensembles) of vacancies. In the case of H 2 dissociation on Pd-a process of interest in many industrial reactions, including hydrogenation and fuel cell technologies -a recent scanning tunneling microscopy (STM) study [1] has revealed that the classically assumed mechanism where diatomic molecules require ensembles of two empty sites is too simplistic [1]. Indeed, Mitsui et al [1,2] have found that near saturation coverage the sites for the facile molecular dissociation on Pd(111) require ensembles of three or more H-free nearest neighbors fcc sites.…”

mentioning

confidence: 99%

“…In the case of H 2 dissociation on Pd-a process of interest in many industrial reactions, including hydrogenation and fuel cell technologies -a recent scanning tunneling microscopy (STM) study [1] has revealed that the classically assumed mechanism where diatomic molecules require ensembles of two empty sites is too simplistic [1]. Indeed, Mitsui et al [1,2] have found that near saturation coverage the sites for the facile molecular dissociation on Pd(111) require ensembles of three or more H-free nearest neighbors fcc sites. Holloway [3] has suggested that such an unexpected result could be due to chemical selfpoisoning of the surface originated by adsorbed hydrogen, further hindering the activity by increasing the dissociation barrier.…”

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confidence: 99%

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When Langmuir Is Too Simple:H2Dissociation on Pd(111) at High Coverage

López

Łodziana²,

Illas

et al. 2004

Phys. Rev. Lett.

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Recent experiments of H 2 adsorption on Pd(111) [T. Mitsui et al., Nature (London) 422, 705 (2003)] have questioned the classical Langmuir picture of second order adsorption kinetics at high surface coverage requiring pairs of empty sites for the dissociative chemisorption. Experiments find that at least three empty sites are needed. Through density functional theory, we find that H 2 dissociation is favored on ensembles of sites that involve a Pd atom with no direct interaction with adsorbed hydrogen. Such active sites are formed by aggregation of at least 3 H-free sites revealing the complex structure of the ''active sites.'' DOI: 10.1103/PhysRevLett.93.146103 PACS numbers: 68.43.Bc, 68.37.Ef, 82.45.Jn, 82.65.+r Under operating conditions, heterogeneously catalyzed chemical reactions take place on surfaces with dense layers of adsorbates. In order to adsorb on such a surface the reactant molecules must find empty surface sites (active sites) created either by one missing adsorbate (vacancy) or by aggregates (ensembles) of vacancies. In the case of H 2 dissociation on Pd-a process of interest in many industrial reactions, including hydrogenation and fuel cell technologies -a recent scanning tunneling microscopy (STM) study [1] has revealed that the classically assumed mechanism where diatomic molecules require ensembles of two empty sites is too simplistic [1]. Indeed, Mitsui et al. [1,2] have found that near saturation coverage the sites for the facile molecular dissociation on Pd(111) require ensembles of three or more H-free nearest neighbors fcc sites. Holloway [3] has suggested that such an unexpected result could be due to chemical selfpoisoning of the surface originated by adsorbed hydrogen, further hindering the activity by increasing the dissociation barrier. An alternative mechanism involves the suppression of energy dissipation channels of the exothermic dissociation reaction [3]. This in turn could be due to (a) modification of the d-band occupation by adsorbed H that would alter the rate of electron-hole pair generation or (b) by surface stiffening, which would reduce phonon excitations. Clearly, the structure and electronic properties of the hydrogen-free ensembles and their effect on the molecular dissociation are fundamental questions that have not been addressed until now.In this Letter we provide an explanation of the STM observations. In addition, we have been able to determine the detailed structure and geometry of the active ensemble of three sites. Because of the rapid motion of H on the surface, the STM experiments could only determine that the number of sites must be larger than two. The actual geometry of the vacancy ensemble, however, is not directly available. The nonobservation of static (in the time scale of seconds) sites of three vacancies surrounding an hcp hollow site (labeled V H ), however, indicates that this site cannot be the active one in the H 2 dissociation. We show that this is indeed the case and that the active site must contain at least one Pd atom without a dir...

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Section: H Y S I C a L R E V I E W L E T T E R S Week Ending 1 Octobementioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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When Langmuir Is Too Simple:H2Dissociation on Pd(111) at High Coverage

López

Łodziana²,

Illas

et al. 2004

Phys. Rev. Lett.

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“…Pd͑111͒ has been intensely investigated in the context of hydrogenation catalysis, electrolysis, and hydrogen purification. 20 This metal surface acts as a catalyst for the dissociation of H 2 molecules into H atoms 21,22 and is capable of storing hydrogen both on the surface [23][24][25] and in the subsurface region. 26,27 Thus, the affinity of the Pd͑111͒ surface towards hydrogen adsorption can be used as the regulator for the hydrogen transfer process between adsorbed building blocks and the substrate.…”

Section: Introductionmentioning

confidence: 99%

Coexistence of one- and two-dimensional supramolecular assemblies of terephthalic acid on Pd(111) due to self-limiting deprotonation

Cañas‐Ventura

Klappenberger

Clair

et al. 2006

The Journal of Chemical Physics

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The adsorption of terephthalic acid ͓C 6 H 4 ͑COOH͒ 2 , TPA͔ on a Pd͑111͒ surface has been investigated by means of scanning tunneling microscopy ͑STM͒, x-ray photoelectron spectroscopy, and near-edge x-ray absorption fine structure spectroscopy under ultrahigh vacuum conditions at room temperature. We find the coexistence of one-͑1D͒ and two-dimensional ͑2D͒ molecular ordering. Our analysis indicates that the 1D phase consists of intact TPA chains stabilized by a dimerization of the self-complementary carboxyl groups, whereas in the 2D phase, consisting of deprotonated entities, the molecules form lateral ionic hydrogen bonds. The supramolecular growth dynamics and the resulting structures are explained by a self-limiting deprotonation process mediated by the catalytic activity of the Pd surface. Our models for the molecular ordering are supported by molecular mechanics calculations and a simulation of high resolution STM images.

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“…For this reason, the adsorption and absorption of hydrogen by Pd has been the subject of much experimental and theoretical work (6,(8)(9)(10)(11)(12)(13)(14). It is known that hydrogen can occupy subsurface sites that are stable absorption sites below the topmost surface layer of Pd atoms.…”

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confidence: 99%

Observation and manipulation of subsurface hydride in Pd{111} and its effect on surface chemical, physical, and electronic properties

Sykes

Fernandez-Torres

Nanayakkara

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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We report the observation and manipulation of hydrogen atoms beneath the surface of a Pd{111} crystal by using low-temperature scanning tunneling microscopy. These subsurface hydride sites have been postulated to have critical roles in hydrogen storage, metal embrittlement, fuel cells, and catalytic reactions, but they have been neither observed directly nor selectively populated previously. We demonstrate that the subsurface region of Pd can be populated with hydrogen atoms from the bulk by applying voltage pulses from a scanning tunneling microscope tip. This phenomenon is explained with an inelastic excitation mechanism, whereby hydrogen atoms in the bulk are excited by tunneling electrons and are promoted to more stable sites in the subsurface region. We show that this selectively placed subsurface hydride affects the electronic, geometric, and chemical properties of the surface. Specifically, we observed the effects of hydride formation on surface deformation and charge and on adsorbed hydrogen on the surface. Hydrogen segregation and overlayer vacancy ordering on the Pd{111} have been characterized and explained in terms of the surface changes attributable to selective hydrogen occupation of subsurface hydride sites in Pd{111}.atomic manipulation ͉ catalysis ͉ palladium ͉ hydrogen ͉ scanning tunneling microscopy

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Dissociative hydrogen adsorption on palladium requires aggregates of three or more vacancies

Cited by 301 publications

References 8 publications

When Langmuir Is Too Simple:H2Dissociation on Pd(111) at High Coverage

When Langmuir Is Too Simple:H2Dissociation on Pd(111) at High Coverage

Coexistence of one- and two-dimensional supramolecular assemblies of terephthalic acid on Pd(111) due to self-limiting deprotonation

Observation and manipulation of subsurface hydride in Pd{111} and its effect on surface chemical, physical, and electronic properties

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