Direct Conversion of Methane to Methanol under Mild Conditions over Cu-Zeolites and beyond

Tomkins, Patrick; Ranocchiari, Marco; Bokhoven, Jeroen A. van

doi:10.1021/acs.accounts.6b00534

Cited by 343 publications

(326 citation statements)

References 55 publications

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“…The gas‐phase partial oxidation of methane has been reported over Fe‐ or Cu‐zeolites using N 2 O, O 2 , and H 2 O as oxidants. However, most reactions can only proceed at relatively high temperatures (>200 °C) resulting in low product yields . On the other hand, much higher yields of methane oxygenates have been reported in a liquid‐phase system .…”

Section: Catalytic Performance For the Selective Oxidation Of Methanementioning

confidence: 99%

Aqueous‐Phase Selective Oxidation of Methane with Oxygen over Iron Salts and Pd/C in the Presence of Hydrogen

Kang

Park

2019

ChemCatChem

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Direct conversion of methane into value‐added chemicals is a challenging but worthwhile subject. In this communication, the direct conversion of methane into methane oxygenates was achieved in an aqueous solution at room temperature using iron salts and Pd/C as catalysts and hydrogen peroxide as an oxidant. The hydrogen peroxide can be directly added or generated in situ from hydrogen and oxygen. The Pd/C catalyst greatly enhanced the reaction rate together with the iron salts. The effect of some parameters such as reaction temperature, reaction time, pH, acid type, and catalyst amount on the yields of the methane oxygenates was also investigated. When hydrogen peroxide was directly added, the turnover frequency (TOF), defined as the moles of methane oxygenates per moles of Fe per unit time, at 293 K was 29 h−1 at pH=2.3. The TOF at 293 K was 42 h−1 at pH=1.3 with in situ generated hydrogen peroxide from hydrogen and oxygen.

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Section: Catalytic Performance For the Selective Oxidation Of Methanementioning

confidence: 99%

Aqueous‐Phase Selective Oxidation of Methane with Oxygen over Iron Salts and Pd/C in the Presence of Hydrogen

Kang

Park

2019

ChemCatChem

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“…Such species can bring about new catalytic functionalities expanding thus the scope of application of the zeolite catalysts. For example, the modification of zeolites with transition metal ions, e. g. with Cu 2+ , Fe 2+/3+ , Co 2+ or Mn 2+ bring about the redox activity needed for such important processes as the selective methane oxidation,, catalytic NO x reduction and the catalytic conversion of biomass‐derived oxygenates . The introduction of Ga 3+ or Zn 2+ gives rise to strong Lewis acid sites that are active in dehydrogenation and dehydroaromatization of light alkanes…”

Section: Introductionmentioning

confidence: 99%

The Nature and Catalytic Function of Cation Sites in Zeolites: a Computational Perspective

Pidko

2018

ChemCatChem

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Zeolites have a broad spectrum of applications as robust microporous catalysts for various chemical transformations. The reactivity of zeolite catalysts can be tailored by introducing heteroatoms either into the framework or at the extraframework positions that gives rise to the formation of versatile Brønsted acid, Lewis acid and redox‐active catalytic sites. Understanding the nature and catalytic role of such sites is crucial for guiding the design of new and improved zeolite‐based catalysts. This work presents an overview of recent computational studies devoted to unravelling the molecular level details of catalytic transformations inside the zeolite pores. The role of modern computational chemistry in addressing the structural problem in zeolite catalysis, understanding reaction mechanisms and establishing structure‐activity relations is discussed. Special attention is devoted to such mechanistic phenomena as active site cooperativity, multifunctional catalysis as well as confinement‐induced and multisite reactivity commonly encountered in zeolite catalysis.

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“…[1] Ap romising stepwise process over copperexchanged zeolites has been suggested;h owever, the mechanistic details of this zeolite-catalyzed conversion are still not understood. [1][2][3][4] Another open question deals with the role of the nature of the oxidant, as well as the mechanism of methane oxidation and regeneration of the copper oxide active site. [1][2][3][4] Another open question deals with the role of the nature of the oxidant, as well as the mechanism of methane oxidation and regeneration of the copper oxide active site.…”

mentioning

confidence: 99%

The Effect of the Active‐Site Structure on the Activity of Copper Mordenite in the Aerobic and Anaerobic Conversion of Methane into Methanol

2018

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Samples of the zeolite mordenite with different Si/Al ratios were used to synthesize materials with monomeric and oligomeric copper sites that are active in the direct conversion of methane into methanol. A comparison of two reactivation protocols with oxygen (aerobic oxidation) and water (anaerobic oxidation), respectively, revealed that such copper-oxo species possess different reactivity towards methane and water. We show for the first time that oligomeric copper species exhibit high activity under both aerobic and anaerobic activation conditions, whereas monomeric copper sites produce methanol only in aerobic processes.

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Direct Conversion of Methane to Methanol under Mild Conditions over Cu-Zeolites and beyond

Cited by 343 publications

References 55 publications

Aqueous‐Phase Selective Oxidation of Methane with Oxygen over Iron Salts and Pd/C in the Presence of Hydrogen

Aqueous‐Phase Selective Oxidation of Methane with Oxygen over Iron Salts and Pd/C in the Presence of Hydrogen

The Nature and Catalytic Function of Cation Sites in Zeolites: a Computational Perspective

The Effect of the Active‐Site Structure on the Activity of Copper Mordenite in the Aerobic and Anaerobic Conversion of Methane into Methanol

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