Greatly facilitated oxygen vacancy formation in ceria nanocrystallites

Migani, Annapaola; Vayssilov, Georgi N.; Bromley, Stefan T.; Illas, Francesc; Neyman, Konstantin M.

doi:10.1039/c0cc01091j

Cited by 172 publications

(239 citation statements)

References 27 publications

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“…In this regard, undoped TiO 2 should not be a very good catalyst since the formation energy of an oxygen vacancy in the (110) surface is 3.66 eV from DFT+U 40,41 , however an energy from periodic B3-LYP studies was not given 41,42 . It is possible that small clusters of TiO 2 could be 30 more favourable for oxygen vacancy formation, as it is generally the case that small clusters are more reactive than their bulk counterpart; this has been discussed for ceria clusters recently 43 . We determine stable adsorption configurations for the TiO 2 35 clusters on the rutile (110) surface and study the electronic properties of these structures as well as their reactivity in terms of oxygen vacancy formation.…”

Section: Introductionmentioning

confidence: 99%

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Reactivity of sub 1 nm supported clusters: (TiO2)n clusters supported on rutile TiO2 (110)

Iwaszuk

Nolan

2011

Phys. Chem. Chem. Phys.

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Access to the full text of the published version may require a subscription. surface. We find that all three clusters adsorb strongly with adsorption energies ranging from -3 eV to -4.5 eV. The more stable adsorption structures show a larger number of new Ti-O bonds formed between the cluster and the surface. These new bonds increase the coordination of cluster Ti and O as well as surface oxygen, so that each has more neighbours. The electronic structure shows that the top of the valence band is made up of cluster derived states, while the conduction band is made 15 up of Ti 3d states from the surface, resulting in a reduction of the effective band gap and spatial separation of electrons and holes after photon absorption, which shows their potential utility in photocatalysis. To examine reactivity, we study the formation of oxygen vacancies in the clustersupport system. The most stable oxygen vacancy sites on the cluster and show formation energies that are significantly lower than in bulk TiO 2 , demonstrating the usefulness of this composite 20 system for redox catalysis. Rights © The Royal Society of Chemistry 2011. This is the Accepted

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Section: Introductionmentioning

confidence: 99%

“…To model the rutile (110) surface, we use a three dimensional periodic slab model and a plane wave basis set to describe the valence electronic wave functions within the VASP code 43 . The cut-off for the kinetic energy is 396 eV.…”

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confidence: 99%

Reactivity of sub 1 nm supported clusters: (TiO2)n clusters supported on rutile TiO2 (110)

Iwaszuk

Nolan

2011

Phys. Chem. Chem. Phys.

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“…We may only speculate that a relatively higher intensity of the 1108 cm -1 band on particles, commonly assigned to methoxy in atop geometry and which, on the basis of DFT calculations [21], is less stable compared to adsorption on oxygen vacancy, would be consistent with the methanol adsorption on low-coordinated Ce sites present on the particle edges. In addition, the energy of formation of an oxygen vacancy on the surfaces of nanoparticles has been shown to be significantly lower than that of planar surfaces, which leads to much higher oxygen-vacancy concentrations in the nanoparticles, and this property is strongly dependent upon size for small particles [7][8][9]. Moreover, the most energetically favored oxygen vacancies are created at edge sites [8].…”

Section: Figurementioning

confidence: 99%

“…In the case of ceria, density functional theory (DFT) calculations have shown that the formation of an oxygen vacancy is energetically favored on the surfaces of ceria nanoparticles in comparison to extended ceria surfaces [7][8][9]. Indeed, experimental studies have revealed that nanoparticles of ceria have the capacity to support a high concentration of defects and reduced species, which are present in only minute quantities on planar surfaces [10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Methanol Reactivity on Silica-Supported Ceria Nanoparticles

2014

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Ceria (CeO 2 ) has been used in a number of catalytic processes, either as a support or promoter. For a better understanding of the factors that control the reactivity of ceria, we have used well-ordered CeO 2 (111) films and ceria nanoparticles supported on an ordered SiO 2 film, as model catalysts. The systems were examined in the dehydrogenation of methanol to formaldehyde as a test reaction by using the techniques of infrared spectroscopy and temperature programmed desorption. The results revealed low-temperature reactivity (below 450 K) for supported ceria particles that is not present on ordered films, which show reactivity at 565 K. The results indicate that low-coordinated sites play an important role in the methanol reactivity on ceria.

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“…Cerium dioxide nanoparticles have been shown to have better catalytic performance than bulk material but the detailed mechanism of oxygen buffering is relatively poorly understood. Nanoparticle surfaces are thought to play an important role but prediction of surface configurations in this system using density functional theory, is not straightforward [3]. Atomic force microscopy can provide experimental verification of theoretically predicted structures for bulk single crystals [4] but it has not previously been possible to determine the surface chemistry of active oxide nanoparticles experimentally [5].…”

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confidence: 99%

Understanding the In-Situ Reaction of Cerium Oxide Nanoparticles Using Aberration Corrected Exit Wave Restoration and EELS

et al. 2011

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Cerium dioxide, CeO 2 is an important oxide and has a wide range of energy-related applications including automotive three-way catalytic converters (TWCC), as a catalyst and a catalyst support for oxidation and reduction reactions and as an electrolyte for solid oxide fuel cells. The ability of CeO 2 to change the oxidation state of Ce between Ce 3+ and Ce 4+ [1] combined with the mobility of oxygen anions within the CeO 2 (fluorite) lattice at relatively low temperatures [2] has played a critical role in its catalytic functionalities. Cerium dioxide nanoparticles have been shown to have better catalytic performance than bulk material but the detailed mechanism of oxygen buffering is relatively poorly understood. Nanoparticle surfaces are thought to play an important role but prediction of surface configurations in this system using density functional theory, is not straightforward [3]. Atomic force microscopy can provide experimental verification of theoretically predicted structures for bulk single crystals [4] but it has not previously been possible to determine the surface chemistry of active oxide nanoparticles experimentally [5].In this paper we use spherical aberration corrected transmission electron microscopy (TEM) combined with computational exit wave restoration [6] in order to determine the surface termination of cerium dioxide nanoparticles. We have simulated exit wavefunctions for {100} and {111} surfaces with different terminations at thicknesses up to 10nm using the multislice approach (FIG. 1). By comparison of line scans extracted from these simulations with the experimentally determined phase of the restored exit wavefunction (FIG. 2) we are able to distinguish between oxygen and metal terminated surfaces. Our results verify for the first time theoretical predicted models [5].It is well known that cerium dioxide is sensitive to the electron beam [1]. Here we take advantage of this electron beam sensitivity to study the change in the surface structure of ceria nanoparticles before and after an in-situ beam induced reduction reaction at ambient temperature. The oxidation state of cerium can be determined using electron energy loss spectroscopy (EELS). We combine our exit wave restoration surface studies with high spatial resolution EELS mapping in order to study changes in the oxidation state of ceria as a function of both electron beam irradiation and distance from the {111} surface.

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Greatly facilitated oxygen vacancy formation in ceria nanocrystallites

Abstract: The formation of oxygen vacancies in nanoparticles Ce(n)O(2n) (n < or = 80), studied using density-functional calculations, is found to be greatly facilitated compared to extended surfaces, which explains the observed spectacular reactivity of nanostructured ceria.

Cited by 172 publications

References 27 publications

Reactivity of sub 1 nm supported clusters: (TiO2)n clusters supported on rutile TiO2 (110)

Reactivity of sub 1 nm supported clusters: (TiO2)n clusters supported on rutile TiO2 (110)

Methanol Reactivity on Silica-Supported Ceria Nanoparticles

Understanding the In-Situ Reaction of Cerium Oxide Nanoparticles Using Aberration Corrected Exit Wave Restoration and EELS

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