Direct Imaging of Octahedral Distortion in a Complex Molybdenum Vanadium Mixed Oxide

Lunkenbein, Thomas; Girgsdies, Frank; Wernbacher, Anna Maria; Noack, Joachim; Auffermann, Gudrun; Yasuhara, Akira; Klein-Hoffmann, Achim; Ueda, Wataru; Eichelbaum, Maik; Trunschke, Annette; Schlögl, Robert; Willinger, Marc Georg

doi:10.1002/anie.201502236

Cited by 26 publications

(42 citation statements)

References 27 publications

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“…This postulate renders the precise structure determination of the oxide phase in question into a decisive [32][33][34][35][36][37][38][39] experiment. It is noted here that with the increasing precision of structured determination [40] not only intergrowth of minority phases that cannot be seen easily with diffraction methods but also local dynamics at interconnection sites of polyhedra supporting the notion of surface reconstruction in termination phases have been observed [41,42] experimentally.…”

Section: The Empirical Conceptual Basissupporting

confidence: 72%

Selective Oxidation: From a Still Immature Technology to the Roots of Catalysis Science

Schlögl

2016

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The design of heterogeneous selective oxidation catalysts based upon complex metal oxides is governed at present by a set of empirical rules known as “pillars of oxidation catalysis”. They serve as practical guidelines for catalyst development and guide the reasoning about the catalyst role in the process. These rules are, however, not based upon atomistic concepts and thus preclude their immediate application in for example computer-aided search strategies. The present work extends the ideas of the pillar rules and develops the concept of considering a selective oxidation catalyst as enabler for the execution of a reaction network. The enabling function is controlled by mutual interactions between catalyst and reactants. The electronic structure of the catalyst is defined as a bulk semiconductor with a surface state arising form a terminating over layer being different from the structure of the bulk. These components that can be identified by in situ analytical methods form a chemical system with feedback loops, which is responsible for generating selectivity during execution of the reaction network. This concept is based upon physical observables and could allow for a design strategy based upon a kinetic description that combines the processes between reactants with the processes between catalyst and reactants. Such kinetics is not available at present. Few of the constants required are known but many of them are accessible to experimental determination with in situ techniques

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Section: The Empirical Conceptual Basissupporting

confidence: 72%

Selective Oxidation: From a Still Immature Technology to the Roots of Catalysis Science

Schlögl

2016

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“…5,6 Among the huge variety of functional materials, high-performance catalysts, such as multimetallic molybdenum-and vanadium-based oxides, which can crystallize in an open crystal structure, are highly susceptible to geometric and compositional defects, such as different cation occupancies, polyhedral distortions or structural reconnectivities. 2,4,[7][8][9] Prominent oxides of this family have an orthorhombic unit cell (space group: Pba2) and crystallize in the so-called M1 structure. The unit cell of the M1 structure is composed of 44 metal atoms that are distributed over 13 crystallographic different metal sites (S).…”

Section: A Introductionmentioning

confidence: 99%

“…[10][11][12] These channels can be partially occupied by cationic species of tellurium, antimony, vanadium or ammonium. 7,[10][11][12][13] Furthermore, complex molybdenum and vanadium mixed oxides represent non-stoichiometric compounds. Thus, in order to accomplish charge neutrality, the intrinsic oxidation states of molybdenum and vanadium within these materials depend on the metal and oxygen composition.…”

Section: A Introductionmentioning

confidence: 99%

Site specific and localized structural displacements in open structured multimetallic oxides

et al. 2020

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“…The typical materials are porous frameworks based on ring-shaped [P 8 W 48 O 184 ] unit 14,15 , [MnV 13 O 38 ] unit 16 , and pentagon [Mo 6 O 21 ] units 17 . However, the current materials suffer from problems that include poor structural diversity, unopened micropores 18 , and low surface area and porosity 18,19 . Therefore, new progresses in obtaining zeolitic materials with all-transition metal oxides that would increase the diversity of material design are strongly desired by material scientists.…”

Section: Introductionmentioning

confidence: 99%

A zeolitic vanadotungstate family with structural diversity and ultrahigh porosity for catalysis

et al. 2018

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Design of the structure and composition of crystalline microporous inorganic oxides is of great importance in catalysis. Developing new zeolites is one approach towards this design because of the tunable pore system and high thermal stability. Zeolites are limited to main group elements, which limits their applications in redox catalysis. Another promising choice is zeolitic transition metal oxides providing both porosity and redox activity, thereby further expanding the diversity of porous materials. However, the examples of zeolitic transition metal oxides are rare. Here, we report a new class of zeolitic vanadotungstates with tunable frameworks exhibiting a large porosity and redox activity. The assembly of [W4O16]8− units with VO2+ forms two isomeric porous frameworks. Owing to the complex redox properties and open porosity, the vanadotungstates efficiently catalyse the selective reduction of NO by NH3. This finding provides an opportunity for design and synthesis of inorganic multifunctional materials for future catalytic applications.

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Direct Imaging of Octahedral Distortion in a Complex Molybdenum Vanadium Mixed Oxide

Cited by 26 publications

References 27 publications

Selective Oxidation: From a Still Immature Technology to the Roots of Catalysis Science

Selective Oxidation: From a Still Immature Technology to the Roots of Catalysis Science

Site specific and localized structural displacements in open structured multimetallic oxides

A zeolitic vanadotungstate family with structural diversity and ultrahigh porosity for catalysis

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