Epitaxial growth of CeO2(111) film on Ru(0001): Scanning tunneling microscopy (STM) and x-ray photoemission spectroscopy (XPS) study

Hasegawa, T.; Shahed, Syed Mohammad Fakruddin; Sainoo, Yasuyuki; Beniya, Atsushi; Isomura, Noritake; Watanabe, Yoshihide; Komeda, Tadahiro

doi:10.1063/1.4849595

Cited by 67 publications

(56 citation statements)

References 44 publications

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“…3(b) by fitting the spectrum with 4 Gaussian functions at 530.2 eV (peak 1), 531.4 eV (peak 2), 532.6 eV (peak 3) and 533.3 eV (peak 4). Peak 1 and 2 are assigned to oxygen bound to Ce 4+ and Ce 3+ , respectively2324 whereas peak 3 is assigned to hydroxyls and/or H 2 O molecules bound to Ce 3+ 2526. From Peaks 1 and 2, we extract the relative content of Ce 3+ .…”

Section: Resultsmentioning

confidence: 99%

A perfectly stoichiometric and flat CeO2(111) surface on a bulk-like ceria film

Barth

Laffon

Olbrich

et al. 2016

Sci Rep

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In surface science and model catalysis, cerium oxide (ceria) is mostly grown as an ultra-thin film on a metal substrate in the ultra-high vacuum to understand fundamental mechanisms involved in diverse surface chemistry processes. However, such ultra-thin films do not have the contribution of a bulk ceria underneath, which is currently discussed to have a high impact on in particular surface redox processes. Here, we present a fully oxidized ceria thick film (180 nm) with a perfectly stoichiometric CeO2(111) surface exhibiting exceptionally large, atomically flat terraces. The film is well-suited for ceria model studies as well as a perfect substitute for CeO2 bulk material.

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Section: Resultsmentioning

confidence: 99%

A perfectly stoichiometric and flat CeO2(111) surface on a bulk-like ceria film

Barth

Laffon

Olbrich

et al. 2016

Sci Rep

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“…This specific epitaxy is often more stable than the formation of polycrystalline films with (111) surface orientation and random in-plane orientation and it is typically stabilized by the post-growth thermal treatment. For example, the Cu(111) surface lattice parameter is almost exactly two-thirds smaller than the cerium oxide one and a 2:3 coincidence cell has been shown to be established [10], while on the Ru(0001) surface, a 5:7 coincidence cell is observed [18,22]. The formation of coincidence cells can be observed in STM images and in low energy electron diffraction (LEED) patterns.…”

Section: The Interface Between Cerium Oxide and Metal Surfaces: Epmentioning

confidence: 99%

“…Ce 3 d XPS spectra can be resolved by a well-established fitting procedure, obtaining the Ce 3+ and Ce 4+ concentration within the XPS probing depth [36,37]. Indeed, other XPS lines, like the Ce 4 d or even the O 1 s , also contain contributions from different oxidation states [22], though the fitting procedure contains more ambiguities. The use of synchrotron radiation allows us to tune the photon energy around the Ce 4 d → 4 f resonance, increasing the sensitivity to the different oxidation states and decreasing the probing depth [6,38].…”

Section: Oxidation State and Morphology Of Ceo2-x Epitaxial Filmsmentioning

confidence: 99%

“…A recent work on the Ru(001) substrate clearly shows that the best morphology in terms of the terrace width and the sharpness of the terrace step edges can be obtained by reactive deposition at temperatures close to the onset temperature for film reduction [22]. In ultrathin films on Pt(111), the post-growth thermal treatments in O 2 at high temperatures (700–1100 K) induce an agglomeration and a flattening of the cerium oxide features observed after growth at room temperature, leading to the formation of islands with definite shape and size, as shown in Figure 3.…”

Section: Oxidation State and Morphology Of Ceo2-x Epitaxial Filmsmentioning

confidence: 99%

“…More recent studies use the reactive growth of cerium in oxygen atmosphere, followed by a post-growth thermal treatment—also in oxygen atmosphere—to optimize the film stoichiometry, structure, and morphology [17,18,19]. Accurate studies of the influence of the growth parameters on the film properties allowed researchers to obtain systems with tunable stoichiometry and size of morphological surface features [6,20,21,22]. Typically, above approximately 1000–1100 K, depending on the substrate used, the oxide films showed to be thermally unstable and they reconverted into complex surface alloys [6,9,15].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Structure, Morphology and Reducibility of Epitaxial Cerium Oxide Ultrathin Films and Nanostructures

Luches

Valeri

2015

Materials

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Cerium oxide is a very interesting material that finds applications in many different fields, such as catalysis, energy conversion, and biomedicine. An interesting approach to unravel the complexity of real systems and obtain an improved understanding of cerium oxide-based materials is represented by the study of model systems in the form of epitaxial ultrathin films or nanostructures supported on single crystalline substrates. These materials often show interesting novel properties, induced by spatial confinement and by the interaction with the supporting substrate, and their understanding requires the use of advanced experimental techniques combined with computational modeling. Recent experimental and theoretical studies performed within this field are examined and discussed here, with emphasis on the new perspectives introduced in view of the optimization of cerium oxide-based materials for application in different fields.

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Ceria Nanocrystals Exposing Wide (100) Facets: Structure and Polarity Compensation

Pan

Nilius

Stiehler

et al. 2014

Adv Materials Inter

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Compact CeO₂(111) films grown on Ru(0001) can be transformed into well-shaped nanoparticles by annealing them in an oxygen-poor environment. With increasing temperature, the particles undergo a distinct shape evolution that finally leads to crystallites exposing wide (100) facets. The atomic structure of the (100) termination is determined with a combination of high-resolution scanning tunneling microscopy and density functional theory. Two surface reconstructions are identified that are compatible with the need to compensate for the intrinsic dipole of the (100) plane and with a substantial reduction of the oxide material. Our study provides insights into the rarely explored (100) surface of ceria, which can be considered as model system for studying chemical processes on the polar termination of reducible oxides

show abstract

Epitaxial growth of CeO2(111) film on Ru(0001): Scanning tunneling microscopy (STM) and x-ray photoemission spectroscopy (XPS) study

Cited by 67 publications

References 44 publications

A perfectly stoichiometric and flat CeO2(111) surface on a bulk-like ceria film

A perfectly stoichiometric and flat CeO2(111) surface on a bulk-like ceria film

Structure, Morphology and Reducibility of Epitaxial Cerium Oxide Ultrathin Films and Nanostructures

Ceria Nanocrystals Exposing Wide (100) Facets: Structure and Polarity Compensation

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