Model in Heterogeneous Catalysis: Surface Science Quo Vadis?

Freund, Hans‐Joachim; Ernst, N.; Risse, Thomas; Hamann, H.; Rupprechter, Günther

doi:10.1002/1521-396x(200109)187:1<257::aid-pssa257>3.0.co;2-9

Cited by 34 publications

(12 citation statements)

References 58 publications

(74 reference statements)

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“…alumina) films as substrates for the metal cluster deposition. The quasi two-dimensional systems prepared that way can be well characterised morphologically by surface analytic techniques [1][2][3] and eventually subjected to an in situ kinetic investigation [4].…”

Section: Introductionmentioning

confidence: 53%

Catalytic reactions on platinum nanofacets: bridging the size and complexity gap

Suchorski

Drachsel

2007

Top Catal

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In this short review we present few selected sections of our own work on the catalytic reactions as studied on a nanoscale using the field emission and field ion microscopies (FEM/FIM) and the corresponding probe-hole techniques: magnetic field ion mass separation combined with the field ion appearance energy spectroscopy (FIAES) and an atom probe with a Wien-filter ion mass selection combined with the time of flight (ToF) and coincidence analyses. We focus on the CO respectively hydrogen oxidation on Pt nanofacets present on an apex of a Pt tip that serves as a model of a single catalytic pellet of a supported catalyst. Exhibiting a heterogeneous surface formed by different orientations, like a catalyst pellet, a Pt tip can be prepared and characterized with atomic resolution. Surface reactions in such a well-defined system can be monitored with a resolution of £ 2 nm by FEM or FIM and the reacting species originating from few selected surface sites can be analyzed by FIAES or ToF in a probe-hole experiment. By using the single tip the usual averaging of data over at least few catalytic pellets of the common array-type model catalyst is avoided and thus a ''smoothing out'' of the characteristics of the single particles can be eliminated. As a result, the correlation of processes on individual nanofacets and fluctuation effects can be studied in situ. Until now, the FIM/FEM techniques are known to be quite successful in studying the oscillating surface reactions on Pt and Rh surfaces. In the present review we concentrate, in turn, on the local reaction kinetics in the nanosized reaction systems as mirrored by spectroscopic measurements and on the fluctuation-induced deviations from the behaviour predicted by macroscopic rate laws.

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Section: Introductionmentioning

confidence: 53%

Catalytic reactions on platinum nanofacets: bridging the size and complexity gap

Suchorski

Drachsel

2007

Top Catal

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“…While this approach has been very successful, it still has its limitations since single crystals often do not contain the range of sites that occur in the analogous high surface area catalysts that are used in industrial practice. Recently studies have started to appear in the literature in which an effort has been made to bridge this so called "materials gap" [5][6][7][8][9][10][11][12]. One promising approach to achieving this goal is use thin films of well-defined nanocrystals as model catalysts.…”

Section: Introductionmentioning

confidence: 99%

Shape-dependence of the thermal and photochemical reactions of methanol on nanocrystalline anatase TiO2

et al. 2016

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Structure-activity relationships and the influence of particle size and shape on the partial-and photo-oxidation of methanol on nanocrystalline anatase TiO 2 was investigated using temperature-programmed desorption. The study employed two distinct nanoparticle morphologies: truncated bipyramids exposing primarily {101} facets, and flatter platelets exposing primarily {001} surfaces, whose nominal sizes ranged from 10 to 25 nm. The platelets were found to be more active for thermally-driven reactions, such as coupling of methoxide groups to produce dimethyl ether, and deoxygenation to produce methane. A dependence of the reactivity of {001} facets for the coupling of methoxide groups to produce dimethyl ether on facet size was also observed. In contrast to the thermally-driven reactions, the bipyramidal nanoparticles were observed to be more active for a range of photochemical reactions, including oxidation and coupling to produce methyl formate, and photo-decomposition of surface methoxide species. This study also shows how well-defined nanocrystals can be used to help bridge the materials gap between studies of single crystal model catalysts and their high surface area industrial analogs.

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“…Since the tools frequently used to study heterogeneous catalysts are limited in their ability to reveal details of oxide surface structure/properties, the atomic-level techniques of surface science offer numerous advantages as alternative investigative procedures, providing useful insights into the physics and chemistry of oxide surfaces [2][3][4][5][6]. Included in this review is the interaction of these oxide surfaces with molecules from the gas phase, followed by the interaction of oxide surfaces with metal and metal oxide deposits, and how these composite systems interact with gas-phase reactants [7][8][9][10][11][12][13][14][15][16][17][18][19][20]. In this chapter we concentrate on recent developments in the investigations of thin oxide films supported on metal single crystals.…”

Section: Introductionmentioning

confidence: 99%

Ultrathin Oxide Films

Freund

Goodman

2008

Handbook of Heterogeneous Catalysis

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The sections in this article are Introduction Magnesium Oxide Mg O (100)/ Mo (100) Mg O (100)/ Ag (100) Mg O (111)/ Mo (110) Nickel Oxide Ni O (100)/ Ni (100), Mo (100) Ni O (111)/ Ni (111) Alumina Alumina/ Ni Al (110) Alumina/ Ni 3 Al (111) Al 2 O 3 (111)/ Ta (110) Al 2 O 3 (111)/ Mo (110) and Cu / Al 2 O 3 (111)/ Mo (110) Silica Si O 2 / Mo (110) Si O 2 / Mo (211) Cu / Si O 2 / Mo (110) Pd / Si O 2 / Mo (110) Au / Si O 2 / Mo (211) and Au / Ti O 2 / Si O 2 / Mo (211) Titania Ti x O y / Mo (100), Mo (110), Pt (111), Ni (110), W (100) Au / Ti O x / Mo (211) Chromia Cr 2 O 3 (111)/ Cr (11O) Vanadia Vanadium Sesquioxide Iron oxides Fe O / Pt (111), Fe 2 O 3 (0001)/ Pt (111), Fe 3 O 4 (001)/ Pt (111) Pd , Au on Iron Oxides Niobia Molybdenum Oxide Ceria Binary Oxides Ni O / Mg O , Ni O / Ca O , Mg O / Ni O , Ca O / Ni O / Mo (100) Conclusions Acknowledgments

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Model in Heterogeneous Catalysis: Surface Science Quo Vadis?

Cited by 34 publications

References 58 publications

Catalytic reactions on platinum nanofacets: bridging the size and complexity gap

Catalytic reactions on platinum nanofacets: bridging the size and complexity gap

Shape-dependence of the thermal and photochemical reactions of methanol on nanocrystalline anatase TiO2

Ultrathin Oxide Films

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