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01.12.2013 | ORIGINAL PAPER

Epitaxial Stabilization of Face Selective Catalysts

verfasst von: James A. Enterkin, Robert M. Kennedy, Junling Lu, Jeffrey W. Elam, Russell E. Cook, Laurence D. Marks, Peter C. Stair, Christopher L. Marshall, Kenneth R. Poeppelmeier

Erschienen in: Topics in Catalysis | Ausgabe 18-20/2013

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Abstract

Selective, active, and robust catalysts are necessary for the efficient utilization of new feedstocks. Face-selective catalysts can precisely modify catalytic properties, but are often unstable under reaction conditions, changing shape and losing selectivity. Herein we report a method for synthesizing stable heterogeneous catalysts in which the morphology and selectivity can be tuned precisely and predictably. Using nanocrystal supports, we epitaxially stabilize specific active phase morphologies. This changes the distribution of active sites of different coordination, which have correspondingly different catalytic properties. Specifically, we utilize the different interfacial free-energies between perovskite titanate nanocube supports with different crystal lattice dimensions and a platinum active phase. By substituting different sized cations into the support, we change the lattice mismatch between the support and the active phase, thereby changing the interfacial free-energy, and stabilizing the active phase in different morphologies in a predictable manner. We correlate these changes in active phase atomic coordination with changes in catalytic performance (activity and selectivity), using the hydrogenation of acrolein as a test reaction. The method is general and can be applied to many nanocrystal supports and active phase combinations.

Vorheriger Artikel Aqueous Phase Glycerol Reforming with Pt and PtMo Bimetallic Nanoparticle Catalysts: The Role of the Mo Promoter

Nächster Artikel Verification of Organic Capping Agent Removal from Supported Colloidal Synthesized Pt Nanoparticle Catalysts

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For completeness, changing the lattice mismatch is not the only way to change the interfacial free-energy and therefore the degree of wetting. Changing the bonding interactions or the composition of the interface will also change the interfacial free-energy. For example, changing to a more oxophilic active phase metal would increase the bond strength and lower the interfacial free-energy. By maintaining the same active phase and substituting one chemically similar cation in the support we minimize such effects in order isolate the effect of the change in lattice mismatch. Preliminary catalytic results on a sample of Pt on commercial SrTiO₃ (non-nanocrystal) showed a lower selectivity than either the SrTiO₃ or Ba_0.5Sr_0.5TiO₃ support. These should have the same bonding effects as nanocrystal SrTiO₃, and support our hypothesis that the structural effect is paramount. However, at this time we cannot completely rule out the possibility that bonding effects make some contribution in addition to the structural effects.

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Titel: Epitaxial Stabilization of Face Selective Catalysts
verfasst von: James A. Enterkin
Robert M. Kennedy
Junling Lu
Jeffrey W. Elam
Russell E. Cook
Laurence D. Marks
Peter C. Stair
Christopher L. Marshall
Kenneth R. Poeppelmeier
Publikationsdatum: 01.12.2013
Verlag: Springer US
Erschienen in: Topics in Catalysis / Ausgabe 18-20/2013
Print ISSN: 1022-5528
Elektronische ISSN: 1572-9028
DOI: https://doi.org/10.1007/s11244-013-0118-y

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