Confinement Effects in Protonation Reactions Catalyzed by Zeolites with Large Void Structures

Zalazar, María Fernanda; Cabral, Néstor Damián; Ojeda, Gonzalo David Romero; Alegre, Clara Iris Aymará; Peruchena, Nélida María

doi:10.1021/acs.jpcc.8b07357

Cited by 16 publications

(12 citation statements)

References 58 publications

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“…In their investigation of mechanism of olefin elimination in the methanol-to-olefin process over different zeolites, Wang et al 57 found that the actual reaction routes for olefin elimination are strongly related to the pore structure of zeolite catalysts; therefore, the confinement of the zeolite pore has a greater effect on the mechanism. Zalazar et al 58 studied the protonation reaction of styrene inside the cavity of acidic H−Y zeolite and analyzed the topology of the electron density of interactions among reactants, transition state, and intermediate products. They found that the zeolite confinement effect is a crucial factor that may affect the catalytic activity.…”

Section: −O H − T 11mentioning

confidence: 99%

Hydrocracking of Fused Aromatic Hydrocarbons Catalyzed by Al-Substituted HZSM-5—A Case Study of 9,10-Dihydroanthracene

zhang

et al. 2020

ACS Catal.

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To investigate the hydrocracking mechanisms of polycyclic aromatic hydrocarbons, we used HZSM-5 with one Al substitution (T1, T3, T5, T7, T11, and T12) as a solid acid catalyst and 9,10-dihydroanthracene as a model substrate on the basis of periodic density functional theory computations. It is found that the intersection of the straight and sinusoidal channels is energetically more favored than the individual sinusoidal and straight channels due to their different local environments. On the basis of the computed Gibbs free energy at 500 °C, the rate-determining step for the formation of 1-benzyl-2-methylbenzene as the first intermediate is the heterolytic activation of H 2 , which is encapsulated in a conjugated frustrated Lewis pair (FLP), generated from the acidic O−H proton transfer to the hydrocarbon substrate. For the subsequent formation of toluene or benzene and o-xylene from 1-benzyl-2-methylbenzene hydrocracking, the rate-determining step, which is the heterolytic activation of H 2 encapsulated in a conjugated FLP, determines the selectivity. On the basis of the apparent Gibbs free energy barriers at 500 °C, the activity has the decreasing order of T5 > T11 > T1 ≈ T12 ≈ T3 ≈ T7. It is noted that there is no correlation between the Gibbs free energy barriers and the acidic strength based on O−H deprotonation Gibbs free energy and the adsorption enthalpy of pyridine as a probe molecule.

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Section: −O H − T 11mentioning

confidence: 99%

Hydrocracking of Fused Aromatic Hydrocarbons Catalyzed by Al-Substituted HZSM-5—A Case Study of 9,10-Dihydroanthracene

zhang

et al. 2020

ACS Catal.

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“…Mesoporous silicate materials have received widespread attention of late due to their applications as supports for catalysis, in separation techniques, and in the confinement of guest molecules. − Siliceous host environments have also generally been important in the realm of heterogeneous catalysis, − where protonation reactions with guest molecules can form carbocation intermediates ,− which can then undergo charge neutralization to give neutral H-adduct free radicals. Such radicals can also be formed by direct H atom transfer/addition reactions to unsaturated bonds in these environments, , a well-known mechanism for hydrogenation reactions in general , and for the hydrogenation of benzene in particular. − Though interfacial interactions of this nature are well-known to be important in surface chemistry, , including for H atom reactivity, there are very few direct measurements of H atom reaction rates in heterogeneous systems, thus providing an important motivation for the present study of the analogue reactions of the muonium atom.…”

Section: Introductionmentioning

confidence: 99%

Studies of Muonium Reactivity with Uncapped Gold Nanoparticles and with Surface-Adsorbed Benzene on These NPs in Porous Silica Hosts

et al. 2019

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Gold nanoparticles (AuNPs) have been a subject of considerable interest in recent years due to both their magnetic and catalytic properties. This paper reports a two-fold study of the reactivity at 300 K of the isotopic hydrogen atom, muonium (Mu = μ + e − ), (i) with bare uncapped AuNPs of different sizes encapsulated in mesoporous (SBA-15) silica hosts, forming a diamagnetic final state in the Mu + AuNP → MuAuNP reaction, and (ii) with surface-adsorbed benzene on these NPs forming the muoniated cyclohexadienyl radical in the Mu + C 6 H 6 → MuC ̇6H 6 addition reaction. The measured muon-spin relaxation rates, λ C , for the chemisorption reaction of Mu with the bare AuNPs show some variation with AuNP size. The Mu + C 6 H 6 addition reaction has been studied over a range of benzene loadings both on bare silica and in the AuNP/silica samples. The measured muon-spin relaxation rates, λ Tot , exhibit a linear dependence on benzene concentration over the full range of loadings in both cases, in accord with an Eley−Rideal model of surface reactivity. Rate constants, k Bz , were determined from this dependence which exhibit a 2−3-fold faster reaction rate on the AuNPs than on the bare silica, suggesting a catalytic effect due to benzene adsorbed on these NP surfaces.

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“…Heterogeneous catalysis has been an important topic in the chemical sciences for many years, ,, in which oxide environments in general , and silicious environments in particular, including mesoporous silica ,,, and zeolites, − have often been used as supports for catalytically active species. The acidic properties of such environments ,− are also important, via proton or H atom transfer reactions to guest molecules ,,,− ,− that can also form free-radical intermediates, important to hydrogenation reactions in general , and for benzene in particular. ,,,, Other than from muon science ,,,− though, exemplified by the present paper as well, there are very few examples of the direct observation of such H-adduct free radicals by spectroscopic techniques, notable exceptions relevant here being the HĊ 6 H 6 cyclohexadienyl radical seen in ZSM-5 zeolite and the ethyl CH 3 ĊH 2 and HĊ 6 H 6 radicals interacting with PdNPs investigated by ESR in silica environments . While ESR would generally be the technique of choice for the investigation of free radicals, the confined geometries of mesoporous silica environments can facilitate radical–radical recombination reactions, reducing signal amplitudes which are generally quite weak to begin with, particularly at higher temperatures, as well as likely affecting the measurements of reaction rates in such confined environments …”

Section: Introductionmentioning

confidence: 75%

Level Crossing Resonance Studies of the Muoniated Cyclohexadienyl Radical (MuĊ₆H₆) Interacting with Uncapped Gold Nanoparticles in Porous Silica Hosts

et al. 2021

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The study of metal nanoparticles (NPs) and gold NPs (AuNPs), in particular, has been a subject of considerable interest in recent years. The present paper reports on the formation of the muoniated cyclohexadienyl radical in the Mu + C6H6 → MuĊ6H6 addition reaction in the same 8 and 10 nm AuNP samples, encapsulated in SBA-15 mesoporous silica, where the spin-relaxation rates λMu were recently reported on [ Fleming Fleming J. Phys. Chem. C201912327628, paper “P1”], but the final state was not identified in that study. The formation of this MuĊ6H6 radical and its interactions with the AuNP surfaces is investigated herein by the technique of avoided level crossing (ALC) resonance spectroscopy, for the same range of Bz loadings as studied earlier. The positions of the level crossings, giving the hyperfine coupling constants (hfcc) for the C–Mu and C–H bonds at the “ipso” position where Mu adds to the ring, are essentially the same as those seen in solid Bz and in bare silica, and hence these hfcc do not distinguish site locations for the surface-adsorbed benzene. The amplitudes of these resonances, which are a measure of the fraction of Mu forming the free-radical final state, do, however, provide such a distinction, being much less for Bz adsorbed in the AuNP/silica samples than in the bare silica. This loss in amplitude is attributed to competitive reaction channels, one forming the MuĊ6H6 free radical interacting with the AuNPs and the other due to formation of diamagnetic final states. An important signpost as to the nature of these competitive reaction channels is provided by the measured widths of the ALC resonances seen. These are surprisingly narrower in the presence of the AuNPs than for the bare silica, implying that the MuĊ6H6 radical is not in direct contact with the AuNPs. These differing possibilities and contrasting mechanisms are discussed.

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Confinement Effects in Protonation Reactions Catalyzed by Zeolites with Large Void Structures

Cited by 16 publications

References 58 publications

Hydrocracking of Fused Aromatic Hydrocarbons Catalyzed by Al-Substituted HZSM-5—A Case Study of 9,10-Dihydroanthracene

Hydrocracking of Fused Aromatic Hydrocarbons Catalyzed by Al-Substituted HZSM-5—A Case Study of 9,10-Dihydroanthracene

Studies of Muonium Reactivity with Uncapped Gold Nanoparticles and with Surface-Adsorbed Benzene on These NPs in Porous Silica Hosts

Level Crossing Resonance Studies of the Muoniated Cyclohexadienyl Radical (MuĊ₆H₆) Interacting with Uncapped Gold Nanoparticles in Porous Silica Hosts

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Confinement Effects in Protonation Reactions Catalyzed by Zeolites with Large Void Structures

Cited by 16 publications

References 58 publications

Hydrocracking of Fused Aromatic Hydrocarbons Catalyzed by Al-Substituted HZSM-5—A Case Study of 9,10-Dihydroanthracene

Hydrocracking of Fused Aromatic Hydrocarbons Catalyzed by Al-Substituted HZSM-5—A Case Study of 9,10-Dihydroanthracene

Studies of Muonium Reactivity with Uncapped Gold Nanoparticles and with Surface-Adsorbed Benzene on These NPs in Porous Silica Hosts

Level Crossing Resonance Studies of the Muoniated Cyclohexadienyl Radical (MuĊ6H6) Interacting with Uncapped Gold Nanoparticles in Porous Silica Hosts

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Level Crossing Resonance Studies of the Muoniated Cyclohexadienyl Radical (MuĊ₆H₆) Interacting with Uncapped Gold Nanoparticles in Porous Silica Hosts