Growth and Structure of Crystalline Silica Sheet on Ru(0001)

Löffler, Daniel; Uhlrich, John J.; Baron, Martín; Yang, Bing; Yu, Xin; Lichtenstein, Leonid; Heinke, Lars; Büchner, Christin; Heyde, Markus; Shaikhutdinov, Shamil K.; Freund, Hans‐Joachim; Włodarczyk, Radosław; Sierka, Marek; Sauer, Joachim

doi:10.1103/physrevlett.105.146104

Cited by 209 publications

(373 citation statements)

References 30 publications

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“…In addition, this film was prepared using isotopically labelled molecular oxygen, 18 O 2 . As expected, a new broad band centered at 1190 cm -1 is observed in IRA-spectrum which is characteristic for three-dimensional, bulk-like ( 18 O-labeled) silica [1,7,9] (see Fig. S2), suggesting that this sample contains also some silica nanoparticles.…”

Section: Pure Silicate Filmsmentioning

confidence: 62%

“…It is well established that the thinnest silica film forms a hexagonal layer of corner-sharing [SiO 4 ] tetrahedra (referred to as "silicatene" in analogy to graphene [5]) which is strongly bound to a metal support through Si-O-Metal linkages [6]. On noble metals such as Ru(0001), Pd(100) and Pt(111), double-layer (or bilayer) silicate films may be grown, which are weakly bound to the support via dispersive forces [7][8][9][10]. In this case, a relatively large space between the silicate sheet and the metal support allows, in principle, small molecules to intercalate the interface, diffuse and ultimately react on the metal surface.…”

Section: Introductionmentioning

confidence: 99%

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Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

et al. 2016

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Abstract. Bilayer silicate films grown on metal substrates are weakly bound to the metal surfaces, which allows ambient gas molecules to intercalate the oxide/metal interface. In this work, we studied the interaction of oxygen with Ru(0001) supported ultrathin silicate and aluminosilicate films at elevated O 2 pressures (10 -5 -10 mbar) and temperatures (450 -923 K). The results show that the silicate films stay essentially intact under these conditions, and oxygen in the film does not readily exchange with oxygen in the ambient. O 2 molecules readily penetrate the film and dissociate on the underlying Ru surface underneath. The silicate layer does however strongly passivate the Ru surface towards RuO 2 (110) oxide formation that readily occurs on bare Ru(0001) under the same conditions. The results indicate considerable spatial effects for oxidation reactions on metal surfaces in the confined space at the interface. Moreover, the aluminosilicate films completely suppress the Ru oxidation, providing some rationale for using crystalline aluminosilicates in anti-corrosion coatings.

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Section: Pure Silicate Filmsmentioning

confidence: 62%

Section: Introductionmentioning

confidence: 99%

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

et al. 2016

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“…17 This film was synthesized based on a preparation of silica (SiO 2 ) bilayer structure first reported by Löffler et al 18 . Using Si and Al co-deposition, some of the Si atoms in the silica film can be replaced by Al, thus resulting in aluminosilicate films.…”

mentioning

confidence: 99%

Exploring Zeolite Chemistry with the Tools of Surface Science: Challenges, Opportunities, and Limitations

Boscoboinik

Shaikhutdinov

2014

Catal Lett

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The complexity of catalysts that the surface science community has been able to address has increased substantially in a systematic manner, starting with metal and oxide single crystal surfaces and evolving to an atomistic description of clusters and nanoparticles on well-defined, planar supports. The next step in adding complexity is now to address surfaces of porous oxide materials, in particular of zeolites, which are the most extensively used catalysts in the industry. The recently reported successful fabrication of well-ordered thin films, consisting of planar arrangement of aluminosilicate polygonal prisms on a metal substrate counting with highly acidic bridging hydroxyl groups on the surface, represents the limiting case of infinitely large pore and cages in zeolites. This model system allows one to study reactions catalyzed by zeolites using the toolkit of surface science. In this Perspective, we describe the zeolitic model system, with its virtues and limitations, as well as the challenges, opportunities and expectations for the future in modelling porous catalysts by a surface science approach.

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“…The stoichiometry of this film is SiO 2.5 . However, on the latter metal surface, a bi-layer film may also be formed, as demonstrated in 2010 by D. Löffler et al (2010), which has SiO 2 stoichiometry, and is only bound to the metal substrate by dispersive forces. The network formed, as viewed from above (e.g., by STM) is identical to the monolayer, but the vibrational spectrum, as also shown in Fig.…”

Section: Silica Filmsmentioning

confidence: 99%

Models for heterogeneous catalysts: studies at the atomic level

Freund

2016

Rend. Fis. Acc. Lincei

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A systematic approach to model heterogeneous catalyst material and characterization at the atomic level is presented. Two examples are used to illustrate the concepts derived from those studies. They document the problems arising on the way to create such model systems and they also indicate possible solutions. The first example is connected with activation of CO 2 at the rim of electron rich MgO (thin film-supported Au islands), and the second example aims at the creation of a model system for the Phillips catalyst for ethylene polymerization and, in particular, the creation of a hydroxylated silica support.

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Growth and Structure of Crystalline Silica Sheet on Ru(0001)

Cited by 209 publications

References 30 publications

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

Oxidation of the Ru(0001) surface covered by weakly bound, ultrathin silicate films

Exploring Zeolite Chemistry with the Tools of Surface Science: Challenges, Opportunities, and Limitations

Models for heterogeneous catalysts: studies at the atomic level

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