Metal clusters on supports: synthesis, structure, reactivity, and catalytic properties

Kulkarni, Apoorva; Lobo‐Lapidus, Rodrigo J.; Gates, Bruce C.

doi:10.1039/c002707n

Cited by 132 publications

(95 citation statements)

References 127 publications

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“…The primary aim of these approaches is to exert greater control over characteristic(s) of the catalyst surface, such as metal cluster or particle size, particle uniformity, alloy composition, and/or complexity of the catalyst support. For example, pioneering work by Gates and co-workers have demonstrated that the deposition of well-defined metal clusters on catalyst supports can be utilized as a technique to generate surfaces containing active clusters with well defined coordination and structure [12][13][14]. Clusters can be deposited via mononuclear precursor techniques (such as Rh(CO) 2 (acac)) or via molecular cluster precursors to generate surfaces preserving a specific metal cluster structure (for example Ir 4 (CO) 12 to generate Ir 4 clusters) [12,13].…”

Section: Introductionmentioning

confidence: 99%

Simulating the Complexities of Heterogeneous Catalysis with Model Systems: Case studies of SiO2 Supported Pt-Group Metals

McClure

Goodman

2011

Top Catal

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Model catalyst surfaces, consisting of vapordeposited metal nanoparticles supported on a planar oxide support, can help to link reactivity studies on well-defined single crystal surfaces with those conducted on high-surface area supported catalysts. When coupled with near atmospheric pressure kinetic and spectroscopic techniques, these well-defined model catalyst surfaces represent a useful approach to combine the power of surface analytical techniques with reactivity studies under relevant reaction conditions. Here, we review recent results of our investigations characterizing the physical and catalytic properties of Pt/SiO 2 and Rh/SiO 2 model catalyst surfaces. As will be discussed, the model catalyst approach can help simulate the complexities of catalytic reactions on supported catalysts, helping to provide insights into the role of particle size, particle morphology, and surface adsorbates in dictating the observed structure-sensitivity (activity and selectivity) during reactions at near atmospheric pressures.

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Section: Introductionmentioning

confidence: 99%

Simulating the Complexities of Heterogeneous Catalysis with Model Systems: Case studies of SiO2 Supported Pt-Group Metals

McClure

Goodman

2011

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“…This results in a strongly anisotropic distribution of nanoparticles on the surface like metallic chains [15], a difficult size control and even more important in a small particle density. An important issue in this context is to find a a e-mail: wolfgang.harbich@epfl.ch way to stabilize these nanostructures [18][19][20][21]. A possible way is to pin the particles via the creation of defects to the surface [22][23][24][25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

Morphology and stability of Au nanoclusters in HOPG nanopits of well-defined depth

et al. 2011

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Abstract. Gold nanoparticles with a diameter comprised between 4 and 6 nm are stabilized in nanosized pits of well defined depth in highly oriented pyrolytic graphite (HOPG). These pits are produced by creation of artificial defects, followed by etching under a controlled oxygen atmosphere. At low Au coverage, clusters are found on the edges of the hexagonal pits maximizing the contact to dangling bonds on graphite multisteps. Larger coverage results in Au beads of surprisingly well defined shape and with a constant bead density per unit length. Most remarkable is the stability of these nanostructures under ambient conditions. Temperatures as high as 650 K do not alter the morphology of the gold clusters. Higher temperatures do not lead to a change of the cluster morphology but to catalytically driven etching of the HOPG substrate.

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“…The catalytic properties of such nanometer and subnanometer clusters can be outstanding, but depend strongly and nonlinearly on cluster size and composition, [1][2][3][4][5][6][7] and also on the nature of the support. 6,[8][9][10][11][12][13] The electronic structure of clusters is reminiscent of molecules, in that important chemical-physical properties can be understood from a molecular orbital (MO) picture, wherein the MOs will be well-separated in energy, rather than having continuous energy bands. 14,15 The support plays the role of a ligand in very small (o1 nm) clusters, capable of actively modifying cluster structures, charge, and other properties (see e.g.…”

Section: Introductionmentioning

confidence: 99%

Pure and Zn-doped Pt clusters go flat and upright on MgO(100)

Shen

Dadras

Alexandrova

2014

Phys. Chem. Chem. Phys.

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Pure and doped sub-nanoclusters can exhibit superb catalytic activity, which, however, strongly depends on their size, shape, composition, and the nature of the support. This work is about surface-deposited sub-nano Pt-based clusters, which are promising catalysts for the reactions of dehydrogenation. Using density functional theory and ab initio calculations, and an ab initio genetic algorithm for finding the global minima of clusters, we found a peculiar effect that Pt 5 and Pt 4 Zn clusters exhibit upon deposition on MgO(100). Both of them change shapes from the gas phase 3-D form to a planar form, and they stand upright on the support. Several reasons are responsible for this behaviour. In part, clusters go flat due to the electron transfer from the support. Indeed, the anionic Pt 5 À and Pt 4 Zn À species are flat also in the gas phase. Charging induces the second-order Jahn-Teller effect (or partial covalency) facilitated by the recruitment of the higher-energy 6p atomic orbitals on Pt into the valence manifold, and that is the reason for the planarization of the anions. Secondly, clusters maximize interactions with the surface O atoms (resulting in further favouring of 2-D structures over 3-D), and avoid contacts with surface Mg atoms (resulting in upright morphologies).

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Metal clusters on supports: synthesis, structure, reactivity, and catalytic properties

Cited by 132 publications

References 127 publications

Simulating the Complexities of Heterogeneous Catalysis with Model Systems: Case studies of SiO2 Supported Pt-Group Metals

Simulating the Complexities of Heterogeneous Catalysis with Model Systems: Case studies of SiO2 Supported Pt-Group Metals

Morphology and stability of Au nanoclusters in HOPG nanopits of well-defined depth

Pure and Zn-doped Pt clusters go flat and upright on MgO(100)

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