Controlling Chemical Reactions in Confined Environments: Water Dissociation in MOF-74

Fuentes-Fernandez, Erika M. A.; Jensen, Stephanie; Tan, Kui; Zuluaga, Sebastian; Wang, Hao; Li, Jing; Thonhauser, Timo; Chabal, Yves J.

doi:10.3390/app8020270

Cited by 12 publications

(5 citation statements)

References 42 publications

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“…This behavior is consistent with prior observations of methanol adsorption in MOF-74 frameworks. 51,75 In all cases, the lowest energy conguration for methanol was found to be binding via the oxygen atom. The cluster model was also used to predict the energetics of CO binding at the OMS, which is also predicted to be exoergic, regardless of whether the CO is bound via carbon or oxygen (Table S6 †).…”

Section: Dft Investigation Of Mof-74 Catalystsmentioning

confidence: 92%

Stabilized open metal sites in bimetallic metal–organic framework catalysts for hydrogen production from alcohols

Snider

Verma

et al. 2021

J. Mater. Chem. A

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Section: Dft Investigation Of Mof-74 Catalystsmentioning

confidence: 92%

Stabilized open metal sites in bimetallic metal–organic framework catalysts for hydrogen production from alcohols

Snider

Verma

et al. 2021

J. Mater. Chem. A

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“…Similar investigations have been also performed in zeolite catalysis. − Raybaud and co-workers established a BEP relationship to estimate the transition states and to predict the initial dealumination sites in zeolites . For the methylation of HCP intermediates, Studt and co-workers reported that the ammonia adsorption enthalpy could be a descriptor for the activity of Brønsted acid sites in the methylation of alkenes in zeolites with different isomorphically substituted metal ions. , In addition to acid strength, the confinement effect of topology, which reflects the stabilizing or repulsive interaction between the reaction intermediates/transition states and zeolite framework, also showed a significant influence on the activity of the zeolite catalyst …”

Section: Introductionmentioning

confidence: 92%

“…33,34 In addition to acid strength, the confinement effect of topology, which reflects the stabilizing or repulsive interaction between the reaction intermediates/transition states and zeolite framework, also showed a significant influence on the activity of the zeolite catalyst. 35 Assuredly, the activity of a zeolite catalyst in the methylation of alkenes and aromatics depends on the topology structure and the acidity; a better understanding of the structure−activity relationship is of benefit to screening for improved catalyst materials and further enhancing the efficiency of current MTH processes. In this work, therefore, the methylation of alkene and aromatic HCP intermediates with methanol was investigated across zeolites of multiple topologies including H-SAPO-34, H-BEA, H-ZSM-5, H-ZSM-22, H-ITQ-13, H-MCM-22, H-FAU, and H-ZSM-12 through DFT and microkinetic calculations.…”

Section: Introductionmentioning

confidence: 99%

Insight into the Methylation of Alkenes and Aromatics with Methanol over Zeolite Catalysts by Linear Scaling Relations

et al. 2020

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It is now known that the methanol to hydrocarbon (MTH) processes over zeolite catalysts comply with the hydrocarbon pool (HCP) mechanism where the methylation of alkenes and aromatics determines the distribution of HCP species and thereon the activity and product selectivity of the zeolite catalyst in MTH to a great extent. In this work, the methylation of alkenes and aromatics in multiple zeolite frameworks was investigated by using density functional theory calculation, to clarify the catalyst structure–activity relationship and predict the distribution of HCP species. Three linear scaling relations (LSRs) were established: first, the energy of transition states is related to the energy of initial states for the successive methylation steps by a new transition-state scaling (TSS) relation; second, a Brønsted–Evans–Polanyi (BEP) relation between the energy barrier and reaction energy is built for the stepwise methylation; and third, the energy barrier and reaction rate of propene methylation are related to pyridine adsorption energy, suggesting that the pyridine adsorption energy can be used as a descriptor for the reactivity of propene in the stepwise methylation. These relations may provide an efficient way to predict the kinetic parameters from a limited number of well-defined energy terms and are helpful in clarifying the structure–activity relationship of the zeolite catalyst in MTH.

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“…At low pressure bands at 3658 and 3575 cm –1 are formed and above 0.1 bar these bands disappear and bands due to H-bonded water (3330, 3220, and 1640 cm –1 ) develop. It was suggested that water dissociates on CPO-27(Zn) but the process cannot be directly followed by IR spectroscopy because of the bands superimposition. , However, the process was monitored by following the adsorption of deuterated water; a sharp band at 970 cm –1 developed and was assigned to O–D bending vibrations in the linker. The band intensified after evacuation at 473 K.…”

Section: Interaction Of Mofs With Guest Moleculesmentioning

confidence: 99%

Power of Infrared and Raman Spectroscopies to Characterize Metal-Organic Frameworks and Investigate Their Interaction with Guest Molecules

et al. 2020

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The variety of functionalities and porous structures inherent to metal-organic frameworks (MOFs) together with the facile tunability of their properties makes these materials suitable for a wide range of existing and emerging applications. Many of these applications are based on processes involving interaction of MOFs with guest molecules. To optimize a certain process or successfully design a new one, a thorough knowledge is required about the physicochemical characteristics of materials and the mechanisms of their interaction with guest molecules. To obtain such important information, various complementary analytical techniques are applied, among which vibrational spectroscopy (IR and Raman) plays an important role and is indispensable in many cases. In this review, we critically examine the reported applications of IR and Raman spectroscopies as powerful tools for initial characterization of MOF materials and for studying processes of their interaction with various gases. Both the advantages and the limitations of the technique are considered, and the cases where IR or Raman spectroscopy is preferable are highlighted. Peculiarities of MOFs interaction with specific gases and some inconsistent band assignments are also emphasized. Summarizing the broad analytical possibilities of the IR and Raman spectroscopies, we conclude that it can be applied in combinations with other techniques to explicitly establish the structure, properties, and reactivity of MOFs.

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Controlling Chemical Reactions in Confined Environments: Water Dissociation in MOF-74

Cited by 12 publications

References 42 publications

Stabilized open metal sites in bimetallic metal–organic framework catalysts for hydrogen production from alcohols

Stabilized open metal sites in bimetallic metal–organic framework catalysts for hydrogen production from alcohols

Insight into the Methylation of Alkenes and Aromatics with Methanol over Zeolite Catalysts by Linear Scaling Relations

Power of Infrared and Raman Spectroscopies to Characterize Metal-Organic Frameworks and Investigate Their Interaction with Guest Molecules

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