Mesosynthesis of ZnO−Silica Composites for Methanol Nanocatalysis

Polarz, Sebastian; Neues, F.; Berg, Maurits W. E. van den; Grünert, Wolfgang; Khodeir, Lamma

doi:10.1021/ja0516514

Cited by 112 publications

(103 citation statements)

References 41 publications

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“…[16][17][18] The liquid ZnO-precursor [{H 3 CZnO-A C H T U N G T R E N N U N G (CH 2 ) 2 OCH 3 } 4 ] was prepared according to the literature. [8] The infiltration experiments were performed under exclusion of air and moisture by using Schlenk techniques, and the mesoporous carbon was carefully dried prior to use. Typically, 0.3 g of the mesoporous carbon powder was stratified with the liquid and undiluted [{H 3 CZnO-A C H T U N G T R E N N U N G (CH 2 ) 2 OCH 3 } 4 ].…”

Section: Methodsmentioning

confidence: 99%

“…[7] Recently, we were able to prepare size-selected ZnO particles in the pores of ordered mesoporous silica materials. [8] The key to success in this preparation was the use of an innovative, organometallic-precursor system resembling ZnO on a molecular scale. [8,9] Due to the potentially large surface area, the idea is very tempting that the nanoporous material itself is composed of a matrix material that is catalytically more relevant than silica.…”

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confidence: 99%

“…[8] The key to success in this preparation was the use of an innovative, organometallic-precursor system resembling ZnO on a molecular scale. [8,9] Due to the potentially large surface area, the idea is very tempting that the nanoporous material itself is composed of a matrix material that is catalytically more relevant than silica. This approach is still rather unexplored, although some success in the synthesis of non-siliceous, ordered mesoporous materials has been made.…”

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confidence: 99%

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Preparation of High‐Surface‐Area Zinc Oxide with Ordered Porosity, Different Pore Sizes, and Nanocrystalline Walls

Polarz

Orlov

Schüth

et al. 2006

Chemistry A European J

129

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Zinc oxide (ZnO) is attracting tremendous research interest due to its vast spectrum of properties and applications. ZnO is an n-type direct band-gap semiconductor with DE gap = 3.37 eV and an exciton-binding energy of 60 meV. Thus, it possesses properties similar to those of gallium nitride, but it is much easier to prepare. Among the interesting features of ZnO are piezoelectric-and electromechanical-coupling properties, and it has been applied for UVlight-emitting diodes, lasers, in photovoltaic solar cells, in UV-photodetectors, gas-sensors, and for varistors.[1] However, more important for this paper is the pivotal role of ZnO as a component in industrial methanol-synthesis catalysts (Cu/ZnO/Al 2 O 3 ).[2] Methanol is increasing in importance because it is believed to be one key compound in future hydrogen-based energy technologies. [3] Because catalytic activity depends highly on dispersion and surface area, [4] an approach used frequently is to immobilize the respective catalytic system on suitable supports. Ordered mesoporous silica materials, such as MCM-41 or SBA-15, [5,6] have proven to be valuable supports for heterogeneous catalysts, due to their unique nanostructure. [7] Recently, we were able to prepare size-selected ZnO particles in the pores of ordered mesoporous silica materials.[8] The key to success in this preparation was the use of an innovative, organometallic-precursor system resembling ZnO on a molecular scale. [8,9] Due to the potentially large surface area, the idea is very tempting that the nanoporous material itself is composed of a matrix material that is catalytically more relevant than silica. This approach is still rather unexplored, although some success in the synthesis of non-siliceous, ordered mesoporous materials has been made. [6,10,11] The preparation of some transition-metal oxides, especially TiO 2 , in a mesoporous state was achieved by using liquid-crystalline templates.[12] A wider spectrum of materials (e.g., mesoporous MgO) could be accessed by using a thermally and mechanically more robust template, an ordered mesoporous carbon material. [11,13] Although there have been some efforts to synthesize nanoporous ZnO with ordered porosity, [14] to the best of our knowledge, the successful preparation of this interesting material has not yet been reported. One of the problems encountered in previous attempts is the reduction of saltlike ZnO precursor, for instance zinc nitrate, in the course of the thermolytic removal of the template.Here, we present the successful preparation of ordered mesoporous ZnO with high surface area. We compared the two methods of preparation, the true liquid-crystal templating and the exotemplating with mesoporous carbons, and obtained ZnO materials with different pore sizes. In both Abstract: Transition-metal-oxide materials possessing ordered mesoporosity have recently attracted significant research interest due to their numerous potential applications. Among them, ordered mesoporous zinc oxide (ZnO) is a very tempting material because of the ...

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Section: Methodsmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Preparation of High‐Surface‐Area Zinc Oxide with Ordered Porosity, Different Pore Sizes, and Nanocrystalline Walls

Polarz

Orlov

Schüth

et al. 2006

Chemistry A European J

129

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“…By embedding the catalytically active component into a well-defined superstructure (e.g., a hierarchically structured mesoporous matrix), it should be possible to simultaneously simplify and miniaturize the supported catalyst [14][15][16][17][18][19][20] and to utilize in the preparation the favorable effects of the spatially confined reaction conditions on the chemistry occurring in the porous solid [21]. However, this approach carries the risk of interference by the pore walls of the matrix.…”

Section: Introductionmentioning

confidence: 99%

Cu/ZnO aggregates in siliceous mesoporous matrices: Development of a new model methanol synthesis catalyst

Berg

Polarz

Ткаченко

et al. 2006

Journal of Catalysis

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Copper and zinc were introduced into mesoporous siliceous matrices with the goal of obtaining model methanol synthesis catalysts with intense interaction between copper and the ZnO promoter. The preparation methods included various aqueous routes starting from acetate solutions (into MCM-48) and a route involving an organometallic step-thermolysis of a liquid heterocubane of Zn 4 O 4 type ([CH 3 ZnOCH 2 CH 2 OCH 3 ] 4 ) in a wormhole-type silica of 5 nm average pore size-followed by aqueous Cu (nitrate) impregnation. The materials were characterized by XRD, nitrogen physisorption, N 2 O frontal chromatography, TPR, and EXAFS, and their methanol synthesis activity was measured at 493 K and normal pressure. In the aqueous preparations with acetate solutions, excessive formation of silicates (particularly zinc silicate) led to damage of the pore system. A significant delay in Cu reduction was assigned to the influence of micropores formed, together with some copper silicate formation. These samples exhibited poorly accessible Cu surface areas despite small Cu particle sizes indicated by EXAFS and disappointing methanol synthesis activity. In contrast to this, a highly active catalyst was obtained via the heterocubane route that meets industrial standards in terms of reaction rate per Cu surface area. Orientation studies (EXAFS at the CuK and ZnK edges) reflecting a redox behavior of the ZnO x component illustrate the potential of this catalyst type for use in basic studies of the Cu-ZnO x interaction in methanol synthesis catalysts.

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“…507 Polarz et al reported the preparation of nanocrystalline, size-selected ZnO inside the pore system of ordered mesoporous silica materials. 508 Highly defined materials containing nanocrystalline ZnO may be interesting as new model systems for methanol catalysis. Sen et al reported the templateassisted fabrication of magnetic mesoporous silicamagnetite nanocomposites 509 which are capable of binding DNA or eluting DNA, and also can be used to extract RNA from bacterial cells.…”

Section: Use Of Confined Spacesmentioning

confidence: 99%

Nanoarchitectonics for Mesoporous Materials

Ariga

Vinu

Yamauchi

et al. 2011

Bulletin of the Chemical Society of Japan

710

411

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Although mesoporous materials have well-defined pore structures, these fine materials can surprisingly be produced by employing a set of conventional and simple procedures such as mixing, heating, filtration, and washing, using low-cost materials. They can be regarded as easy-to-make bulk nanostructured materials. Mesoporous materials have great potential for use in both macroscopic applications and nanotechnology. In this account, we introduce examples of recent developments in mesoporous materials involving innovations in their components and structural designs and concentrating on our own recent progress. These examples include syntheses of mesoporous silica, metal oxides, semiconductive materials, metals, alloys, organic composites, biomaterial composites, carbon, carbon nitride, and boron nitride, as innovative components. As structural innovations for mesoporous materials, various film preparations, pore alignments, and hierarchic structures are described together with their related functions including sensing and controlled release of target molecules. Why Mesoporous Materials? Bulk Quantities and Precise StructuresThere is little doubt that nanotechnology and related technologies are making significant contributions to current research and development which will eventually be felt in our day-to-day lives. Device miniaturization in such products as cellular phones and portable computers has irrevocably changed our lifestyles. Portable devices allow us to work and communicate wherever we are in the world in contrast to the previous situation where machine operation required a human presence. Greater freedom in our work and leisure dispositions should diminish over-concentration of populations in cities and may ultimately reduce energy consumption and waste production.So far, device innovations have been due to development of top-down approaches, especially sophisticated microfabrication techniques. 17 However, those top-down techniques are not useful for materials innovation where chemical processes are used as the operating principle. Rather, so-called bottom-up approaches are expected to create novel functional materials having well-controlled structural features with nanometric precision. Bottom-up approaches rely on self-assembly processes to form selected structures through spontaneous association of atoms, molecules, clusters, and particles. 818 Furthermore, assisted assembly techniques using external influences are provided by LangmuirBlodgett (LB) method 1928 and layer-by-layer (LbL) adsorption 2936 and provide significant contributions for materials' fabrication. According to these concepts, molecular complex formation, 3741 molecular array control, 4252 and microscopic structural design 5361 have been widely investigated leading to generation of a large quantity of scientific knowledge.Ideally, materials should be produced in a series of easy processes to yield bulk quantity without loss of nanometric structural features and some categories of material already satisfy this condition. For exampl...

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Mesosynthesis of ZnO−Silica Composites for Methanol Nanocatalysis

Cited by 112 publications

References 41 publications

Preparation of High‐Surface‐Area Zinc Oxide with Ordered Porosity, Different Pore Sizes, and Nanocrystalline Walls

Preparation of High‐Surface‐Area Zinc Oxide with Ordered Porosity, Different Pore Sizes, and Nanocrystalline Walls

Cu/ZnO aggregates in siliceous mesoporous matrices: Development of a new model methanol synthesis catalyst

Nanoarchitectonics for Mesoporous Materials

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