Morphology and Microstructure of Li/MgO Catalysts for the Oxidative Coupling of Methane

Zavyalova, Ulyana; Geske, Michael; Horn, Raimund; Weinberg, Gisela; Frandsen, Wiebke; Schuster, Manfred Erwin; Schlögl, Robert

doi:10.1002/cctc.201000098

Cited by 73 publications

(62 citation statements)

References 58 publications

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“…When 745 the ratio was 1, the ethylene selectivity was 30% but increased to 746 40% when the ratio was raised to 4. The trend was generally 747 consistent with observations from studies conducted with related 748 and other OMC catalysts [95,[120][121][122][123][124][125][126][127]. Although natural gas is the main feedstock being considered 783 currently, the re-ignited discovery and production of shale gas 784 could shift the trend toward its valorization via the process.…”

supporting

confidence: 87%

Revisiting the oxidative coupling of methane to ethylene in the golden period of shale gas: A review

Galadima

Muraza

2016

Journal of Industrial and Engineering Chemistry

182

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supporting

confidence: 87%

Revisiting the oxidative coupling of methane to ethylene in the golden period of shale gas: A review

Galadima

Muraza

2016

Journal of Industrial and Engineering Chemistry

182

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“…[6] In return it was shown that lithium, which completely desorbs by formation of volatile compounds during the oxidative pretreatment of the catalyst (which involves the loss of all [Li-O] -centers), acts as a structural promoter that favors the formation of terminating higher index planes like {111} or {110}. [2,7] The highest selectivity to C 2+ products was found for pure MgO catalysts, which expose a greater fraction of {111} planes. [8] Inconsistent findings have also been reported with respect to activity.…”

Section: Li-doped Mgo Was Discovered By Lunsford Et Al As An Active mentioning

confidence: 99%

Structure sensitivity of the oxidative activation of methane over MgO model catalysts: I. Kinetic study

Schwach

Hamilton

Thum

et al. 2015

Journal of Catalysis

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The role of surface structure and defects in the oxidative coupling of methane (OCM) was studied over magnesium oxide as a model catalyst. Pure, nano-structured MgO catalysts with varying primary particle size, shape and specific surface area were prepared by sol–gel synthesis, oxidation of metallic magnesium, and hydrothermal post treatments. The initial activity of MgO in the OCM reaction is clearly structure-sensitive. Kinetic studies reveal the occurrence of two parallel reaction mechanisms and a change in the contribution of these pathways to the overall performance of the catalysts with time on stream. The initial performance of freshly calcined MgO is governed by a surface-mediated coupling mechanism involving direct electron transfer between methane and oxygen. The two molecules are weakly adsorbed at structural defects (steps) on the surface of MgO. The proposed mechanism is consistent with high methane conversion, a correlation between methane and oxygen consumption rates, and high C₂H₄ selectivity after short times on stream. The water formed in the OCM reaction causes sintering of the MgO particles and loss of active sites by degradation of structural defects, which is reflected in decreasing activity of MgO with time on stream. At the same time, gas-phase chemistry becomes more important, which includes the formation of ethane by coupling of methyl radicals formed at the surface and the partial oxidation of C₂H₆. The mechanistic concepts proposed in this work (Part I) will be substantiated in Part II by spectroscopic characterization of the catalysts (Schwach et al. [1])

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“…Magnesium oxide (MgO) is an important functional metal oxide that has been widely used in various fields such as catalysis, refractory materials, paints, and superconductors [3,4]. Nanostructured MgO has high surface area and therefore acts as coating agent which helps in increasing the energy conversion efficiency [5].…”

Section: Introductionmentioning

confidence: 99%

Optical and fluorescence properties of MgO nanoparticles in micellar solution of hydroxyethyl laurdimonium chloride

Salem

El‐Nahhal

Hammad

et al. 2015

Chemical Physics Letters

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Morphology and Microstructure of Li/MgO Catalysts for the Oxidative Coupling of Methane

Cited by 73 publications

References 58 publications

Revisiting the oxidative coupling of methane to ethylene in the golden period of shale gas: A review

Revisiting the oxidative coupling of methane to ethylene in the golden period of shale gas: A review

Structure sensitivity of the oxidative activation of methane over MgO model catalysts: I. Kinetic study

Optical and fluorescence properties of MgO nanoparticles in micellar solution of hydroxyethyl laurdimonium chloride

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