Density Functional Theory (DFT) Study To Unravel the Catalytic Properties of M-Exchanged MFI, (M = Be, Co, Cu, Mg, Mn, Zn) for the Conversion of Methane and Carbon Dioxide to Acetic Acid

Montejo-Valencia, Brian D.; Pagán-Torres, Yomaira J.; Martínez-Iñesta, María M.; Curet-Arana, María C.

doi:10.1021/acscatal.7b00844

Cited by 79 publications

(75 citation statements)

References 60 publications

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“…This finding further support the proposal that the radical oxygen is a key factor determining the catalytic activity of the active site for C−H bond activation ,, , . Calculations on a broad range of metal‐exchanged zeolites by Curet‐Arana and co‐workers showed that the barrier for C−H bond cleavage is directly related to the energy of the lowest unoccupied molecular orbital (LUMO) and the electronegativity of active site in the metal exchanged zeolites . A periodic hybrid DFT study by Solans‐Monfort et al on the interaction of model adsorbents with Cu and Fe‐exchanged zeolites highlighted the importance of the local environment of EF sites for their adsorption properties and reactivity …”

Section: Lewis Acidity Of Zeolitesmentioning

confidence: 99%

“…[108,116b, 117, 125] Calculations on a broad range of metal-exchanged zeolites by Curet-Arana and co-workers showed that the barrier for CÀ H bond cleavage is directly related to the energy of the lowest unoccupied molecular orbital (LUMO) and the electronegativity of active site in the metal exchanged zeolites. [126] A periodic hybrid DFT study by Solans-Monfort et al on the interaction of model adsorbents with Cu and Fe-exchanged zeolites highlighted the importance of the local environment of EF sites for their adsorption properties and reactivity. [127] Nørskov and co-workers have computationally screened the activity of wide variety of oxide-and zeolite-based catalysts for the activation of CÀ H bonds in methane.…”

Section: Structure-reactivity Relationshipsmentioning

confidence: 99%

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

Pidko

2018

ChemCatChem

110

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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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Section: Lewis Acidity Of Zeolitesmentioning

confidence: 99%

Section: Structure-reactivity Relationshipsmentioning

confidence: 99%

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

Pidko

2018

ChemCatChem

110

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“…Unfortunately, the reaction is thermodynamically unfavorable under moderate conditions ( G 298K = 71.2 kJ/mol). Many works are devoted to selectively break the C-H bond in CH 4 and simultaneously utilize the inertness of CO 2 to realize C-C coupling for the synthesis of high-value chemicals [3][4][5][6][7]. Most of these works are based on theoretical calculation and experiments which always require additional energy supply (such as plasma), few in-situ characterizations studies have been conducted.…”

Section: Introductionmentioning

confidence: 99%

In-Situ FT-IR Spectroscopy Investigation of CH4 and CO2 Reaction

et al. 2020

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An exclusive trace of CH4 direct carboxylation with CO2 by a stepwise technology was investigated using in-situ FT-IR spectroscopy. The results showed that CH4 was dissociated to atomic hydrogen and M-CHx species on catalyst surface when it was first introduced in the system, then CO2 was inserted into the intermediate to direct carboxylate. Finally, the subsequent adsorption of CH4 provided active hydrogen for the species of previous surface reaction, thus leading to the formation of the product. It was also found that the first introduction of CO2 on the surface of the “clean” catalyst might likely react with surface H species, which had an irreversible effect on the catalytic activity of CH4.

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“…Sustituciones de la zeolita MFI con otros metales como cobre (Cu) y hierro (Fe) también se han estudiado para la activación de CH4 [5]- [7]. La sustitución de Cu se puede dar de dos maneras: Mediante la formación de "oxoclusters" [Cu-O-Cu] 2+ o mediante la sustitución sencilla de Cu +2 en los anillos de MFI (Cu-MFI) [8], [9]. La barrera energética obtenida para la disociación de metano en [Cu-O-Cu] 2+ (82 kJ/mol) es menor que la obtenida en Cu-MFI (129 kJ/mol).…”

Section: Introduccionunclassified

Análisis DFT de zeolita MFI sustituida con magnesio para la activación de metano.

Montejo-Valencia¹

2020

Proceedings of the 18th LACCEI International Multi-Conference for Engineering, Education, and Technology: Engineering, Integrat

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Methane gas reserves (CH4) have been growing exponentially in the United States due to the discovery of new shale gas deposits. CH4 is currently burned to produce synthesis gas, but new alternatives are being sought for its use. This paper discusses the feasibility of Mg-MFI catalyst synthesis for CH4 conversion. A DFT analysis was performed to quantify the effect of the distribution of aluminum atoms in the ring of zeolite MFI exchanged with magnesium (Mg). Our results indicate that the most stable substitution of Al in Mg-MFI is achieved at the T11-T2 crystallographic sites of zeolite. Furthermore, the adsorption energies of CH4 in Mg-MFI reached values of up to-111 kJ/mol, being the strongest adsorption energies reported so far for a zeolite. After the adsorption, the activation of CH4 occurs leading to the formation of an acid Brønsted site in the α ring and the formation of a bond between the methyl (CH3) and Mg. Our results show that the activation of CH4 requires high reaction energies that are in the range between 154 to 266 kJ/mol, suggesting that Mg-MFI would not be a good catalyst for reactions that require CH4 activation.

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Density Functional Theory (DFT) Study To Unravel the Catalytic Properties of M-Exchanged MFI, (M = Be, Co, Cu, Mg, Mn, Zn) for the Conversion of Methane and Carbon Dioxide to Acetic Acid

Cited by 79 publications

References 60 publications

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

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

In-Situ FT-IR Spectroscopy Investigation of CH4 and CO2 Reaction

Análisis DFT de zeolita MFI sustituida con magnesio para la activación de metano.

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