Designing Multifunctionality into Single Phase and Multiphase Metal-Oxide-Selective Propylene Ammoxidation Catalysts

Autor:	James F. Brazdil
Jazyk:	angličtina
Rok vydání:	2018
Předmět:	Chemical process Materials science Process (engineering) Oxide Context (language use) 02 engineering and technology 010402 general chemistry Heterogeneous catalysis lcsh:Chemical technology 01 natural sciences Catalysis lcsh:Chemistry chemistry.chemical_compound lcsh:TP1-1185 Physical and Theoretical Chemistry Process engineering Ammoxidation propylene ammoxidation business.industry epitaxy coherent interface 021001 nanoscience & nanotechnology acrylonitrile selective oxidation 0104 chemical sciences Petrochemical chemistry lcsh:QD1-999 metal-oxide catalysts solid solution 0210 nano-technology business
Zdroj:	Catalysts, Vol 8, Iss 3, p 103 (2018)
ISSN:	2073-4344
Popis:	Multifunctionality is the hallmark of most modern commercial heterogeneous catalyst systems in use today, including those used for the selective ammoxidation of propylene to acrylonitrile. It is the quintessential principle underlying commercial catalyst design efforts since petrochemical process development is invariably driven by the need to reduce manufacturing costs. This is in large part achieved through new and improved catalysts that increase selectivity and productivity. In addition, the future feedstocks for chemical processes will be invariably more refractory than those currently in use (e.g., replacing alkenes with alkanes or using CO2), thus requiring a disparate combination of chemical functions in order to effect multiple chemical transformations with the fewest separate process steps. This review summarizes the key chemical phenomena behind achieving the successful integration of multiple functions into a mixed-metal-oxide-selective ammoxidation catalyst. An experiential and functional catalyst design model is presented that consists of one or both of the following components: (1) a mixed-metal-oxide–solid solution where the individual metal components serve separate and necessary functions in the reaction mechanism through their atomic level interaction in the context of a single crystallographic structure; (2) the required elemental components and their catalytic function existing in separate phases, where these phases are able to interact for the purposes of electron and lattice oxygen transfer through the formation of a structurally coherent interface (i.e., epitaxy) between the separate crystal structures. Examples are provided from the literature and explained in the context of this catalyst design model. The extension of the model concepts to the design of heterogeneous catalysts in general is also discussed.
Databáze:	OpenAIRE
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