Christopher L. Marshall scite author profile

Small clusters are known to possess reactivity not observed in their bulk analogues, which can make them attractive for catalysis. Their distinct catalytic properties are often hypothesized to result from the large fraction of under-coordinated surface atoms. Here, we show that size-preselected Pt(8-10) clusters stabilized on high-surface-area supports are 40-100 times more active for the oxidative dehydrogenation of propane than previously studied platinum and vanadia catalysts, while at the same time maintaining high selectivity towards formation of propylene over by-products. Quantum chemical calculations indicate that under-coordination of the Pt atoms in the clusters is responsible for the surprisingly high reactivity compared with extended surfaces. We anticipate that these results will form the basis for development of a new class of catalysts by providing a route to bond-specific chemistry, ranging from energy-efficient and environmentally friendly synthesis strategies to the replacement of petrochemical feedstocks by abundant small alkanes.

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Catalyst Design with Atomic Layer Deposition

O’Neill¹,

Jackson²,

Lee³

et al. 2015

ACS Catal.

678

587

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Review of Dimethyl Carbonate (DMC) Manufacture and Its Characteristics as a Fuel Additive

Pacheco¹,

Marshall²

1997

Energy Fuels

817

480

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Dimethyl carbonate (DMC) is considered an option for meeting the oxygenate specifications on gasoline and as a means of converting natural gas to a liquid transportation fuel. In this report, the fuel characteristics and known chemical synthesis schemes for DMC are reviewed. Three production schemes have a commercial track record, while others are still under development. The older of the three commercially proven schemes is undesirable because it employs phosgene. The other two commercially proven schemes have a complex mixture of advantages and disadvantages with regard to the synthesis chemistry and are reviewed in greater detail. One other commercially viable production scheme that involves coproduction of either ethylene or propylene glycol is also reviewed. This scheme is still in the development stage and would require a commitment to coproduce the glycol from ethylene or propylene. The authors are not aware of any refiner that either has blended or is blending DMC into gasoline for commercial use.

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Catalytic Applications of Vanadium: A Mechanistic Perspective

et al. 2018

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The chemistry of vanadium has seen remarkable activity in the past 50 years. In the present review, reactions catalyzed by homogeneous and supported vanadium complexes from 2008 to 2018 are summarized and discussed. Particular attention is given to mechanistic and kinetics studies of vanadium-catalyzed reactions including oxidations of alkanes, alkenes, arenes, alcohols, aldehydes, ketones, and sulfur species, as well as oxidative C–C and C–O bond cleavage, carbon–carbon bond formation, deoxydehydration, haloperoxidase, cyanation, hydrogenation, dehydrogenation, ring-opening metathesis polymerization, and oxo/imido heterometathesis. Additionally, insights into heterogeneous vanadium catalysis are provided when parallels can be drawn from the homogeneous literature.

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Stabilization of Copper Catalysts for Liquid‐Phase Reactions by Atomic Layer Deposition

et al. 2013

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Atomic layer deposition (ALD) of an alumina overcoat can stabilize a base metal catalyst (e.g., copper) for liquid-phase catalytic reactions (e.g., hydrogenation of biomass-derived furfural in alcoholic solvents or water), thereby eliminating the deactivation of conventional catalysts by sintering and leaching. This method of catalyst stabilization alleviates the need to employ precious metals (e.g., platinum) in liquid-phase catalytic processing. The alumina overcoat initially covers the catalyst surface completely. By using solid state NMR spectroscopy, X-ray diffraction, and electron microscopy, it was shown that high temperature treatment opens porosity in the overcoat by forming crystallites of γ-Al2 O3 . Infrared spectroscopic measurements and scanning tunneling microscopy studies of trimethylaluminum ALD on copper show that the remarkable stability imparted to the nanoparticles arises from selective armoring of under-coordinated copper atoms on the nanoparticle surface.

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