Stearate‐Based Cu Colloids in Methanol Synthesis: Structural Changes Driven by Strong Metal–Support Interactions

Schimpf, Sabine; Rittermeier, André; Zhang, Xiaoning; Li, Zi‐An; Spasova, Marina; Berg, Mauritz W. E. van den; Farle, Michael; Wang, Yuemin; Fischer, Roland A.; Mühler, Martin

doi:10.1002/cctc.200900252

Cited by 45 publications

(49 citation statements)

References 29 publications

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“…14À17 Copper catalysts are often prepared via coprecipitation, as high loadings can be achieved in combination with high copper dispersion and good stability. 13À15, 18 Alternative methods have been explored such as chemical vapor deposition, 19,20 colloidal routes, 21 and solÀgel synthesis. 22 Preparation via pore volume impregnation is especially desirable because of its practical simplicity and small waste streams.…”

Section: ' Introductionmentioning

confidence: 99%

Copper Nitrate Redispersion To Arrive at Highly Active Silica-Supported Copper Catalysts

Munnik

Wolters

Gabrielsson³

et al. 2011

J. Phys. Chem. C

119

125

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In order to obtain copper catalysts with high dispersions at high copper loadings, the gas flow rate and gas composition was varied during calcination of silica gel impregnated with copper nitrate to a loading of 18 wt % of copper. Analysis by X-ray diffraction (XRD), N2O chemisorption, and transmission electron microscopy (TEM) showed that calcination in stagnant air resulted in very large copper crystallites and a low copper surface area (12 m2·gCu –1). A moderate flow of air was sufficient to greatly enhance the copper surface area (∼90 m2·gCu –1) based on a bimodal particle size distribution of few large crystallites and a highly dispersed phase. Changing to an N2 flow resulted in similar copper surface areas compared to samples calcined in air at the same space velocity, while calcination in a 2% NO/N2 flow resulted in a relatively narrow particle size distribution peaking around 8 nm and a slightly lower copper surface area (84 m2·gCu –1). By use of SBA-15 supported samples, in situ XRD and diffuse reflectance Fourier transform infrared spectroscopy (DRIFTS) showed that the decomposition of copper nitrate in NO occurred via a highly dispersed copper hydroxynitrate phase, while decomposition in N2 or air occurred partly via copper nitrate anhydrate and partly via poorly dispersed copper hydroxynitrate. The high CuO dispersions after calcination in an N2 or air flow were ascribed to the redispersion of copper nitrate anhydrate by interaction with the OH groups of the silica support. By utilization of this redispersion, high copper dispersions on silica gel with concomitant high activities were obtained for the gas-phase hydrogenation of butanal.

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Section: ' Introductionmentioning

confidence: 99%

Copper Nitrate Redispersion To Arrive at Highly Active Silica-Supported Copper Catalysts

Munnik

Wolters

Gabrielsson³

et al. 2011

J. Phys. Chem. C

119

125

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“…The comparison of catalytic activities with reference to industrial catalysts is given in In another such approach, zinc stearate and copper stearate in squalane were reduced with diluted H 2 to yield dark red Cu colloids (5-10 nm) with Zn stearate shell. 78 Here, zinc stearate acts as a stabilizer and is not reduced by H 2 . These colloids showed exceptional activities toward methanol synthesis.…”

Section: Quasihomogeneous Catalystmentioning

confidence: 99%

Nanocatalysis: Activation of Small Molecules and Conversion into Useful Feedstock

Kalidindi

Jagirdar

2013

Nanocatalysis Synthesis and Applications

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“…The catalytic synthesis of methanol from synthesis gas in the liquid‐phase has recently been achieved by using metallic Cu in the colloidal state 18–20. Starting with the synthesis of Zn stearate‐stabilized Cu colloids of defined size and shape an active colloidal state is formed from spherical Cu colloids under catalytic high‐temperature high‐pressure conditions 21. The spherical Cu particles of this active colloidal state are partially covered with ZnO x adspecies and stabilized by octadecanol (Fig.…”

Section: Tem Characterization Of Cu/zno Catalysts For Methanol Syntmentioning

confidence: 99%

Elucidating elementary processes at Cu/ZnO interfaces: A microscopical approach

Zychma

Wansing

Schott

et al. 2013

Physica Status Solidi (b)

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Despite its enormous importance for heterogeneous catalysis, and in particular methanol synthesis, detailed information about the Cu/ZnO interface is still far from being complete. Here we present an overview of recent work carried out using different types of microscopical methods from which the complexity of the problem becomes apparent. In addition to results from transmission electron microscopy (TEM) and scanning electron microscopy (SEM) data also obtained using scanning probe techniques, in particular scanning tunneling microscopy (STM) and atomic force microscopy (AFM) are presented. Special attention is paid to the influence of elevated temperatures on the Cu/ZnO interface.

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Stearate‐Based Cu Colloids in Methanol Synthesis: Structural Changes Driven by Strong Metal–Support Interactions

Cited by 45 publications

References 29 publications

Copper Nitrate Redispersion To Arrive at Highly Active Silica-Supported Copper Catalysts

Copper Nitrate Redispersion To Arrive at Highly Active Silica-Supported Copper Catalysts

Nanocatalysis: Activation of Small Molecules and Conversion into Useful Feedstock

Elucidating elementary processes at Cu/ZnO interfaces: A microscopical approach

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