Aromatic Bromination of <i>N</i>-Phenylacetamide Inside CNTs. Are CNTs Real Nanoreactors Controlling Regioselectivity and Kinetics? A QM/MM Investigation

Marforio, Tainah Dorina; Bottoni, Andreà; Giacinto, Pietro; Zerbetto, Francesco; Calvaresi, Matteo

doi:10.1021/acs.jpcc.7b07296

Cited by 20 publications

(16 citation statements)

References 61 publications

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“…The experiment with SWCNTs of different dimensions confirmed that subtle variations in CNT diameter (i.e., from 6.9 to 9.6 Å) are crucial to get the desired effect. The in silico study of this reaction led to the hypothesis that the non-covalent interactions within CNTs is the main contributing factor to explain the regioselectivity and the kinetics of the reaction [37]. The following examples are dedicated to the second type-reactions where the process occurs inside CNTs and the product remains encapsulated.…”

Section: Nanoreactors-reactions Type I and Iimentioning

confidence: 99%

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Enter the Tubes: Carbon Nanotube Endohedral Catalysis

Iglesias

Melchionna

2019

Catalysts

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The unique morphological characteristics of carbon nanotubes (CNTs) present the intriguing opportunity of exploiting the inner cavity for carrying out chemical reactions. Such reactions are catalysed either by the individual tubes that function both as catalysts and nanoreactors or by additional catalytic species that are confined within the channel. Such confinement creates what is called “confinement effect”, which can result in different catalytic features affecting activity, stability and selectivity. The review highlights the recent major advancements of catalysis conducted within the CNTs, starting from the synthesis of the catalytic composite, and discussing the most notable catalytic processes that have been reported in the last decade.

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Section: Nanoreactors-reactions Type I and Iimentioning

confidence: 99%

“…Molecular model and TEM simulation of a bucky metallocene reorganizing to form a C 70 fullerene (B). Adapted with permission from reference[37]. Copyright (2011) American Chemical Society.…”

mentioning

confidence: 99%

Enter the Tubes: Carbon Nanotube Endohedral Catalysis

Iglesias

Melchionna

2019

Catalysts

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“…Following this hypothesis, increasing attention has been focused during the last years on the use of carbon nanomaterials as catalysts . These materials are particularly interesting and promising for a sustainable chemistry in many industrial processes.…”

Section: Introductionmentioning

confidence: 99%

CNT‐Catalyzed Oxidative Dehydrogenation of Ethylbenzene to Styrene: DFT Calculations Disclose the Pathways

et al. 2019

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Oxygen atoms, in the form of epoxy or carbonyl groups present at the edges of carbon nanotubes, trigger oxidative dehydrogenation of ethylbenzene to styrene. DFT calculations reveal that the process can occur along three pathways. The first two bifurcate from the initial transformation of an epoxide into a hydroxyl group, which occurs via a biradical transition state and the formation of a benzyllike intermediate. The epoxide can further react to release styrene and form a water molecule, as observed experimentally, via a highly exothermic process. Alternatively, in the presence of a second adjacent epoxide, styrene is also produced without water formation along a less exothermic pathway that leaves two hydroxyl groups on the nanotube surface. Along the third pathway, two adjacent carbonyl groups (quinone functionality) also promote the formation of styrene, with energy barriers similar to those calculated in the presence of epoxy groups. These are in the range 36-37 kcal mol À1 . These values that can be easily surmounted at the working temperature used in the experiment (between 450 and 550 8C).[a] Dr.

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“…Computational chemistry could be helpful in this concern, but relatively few computational studies have been published on the operating mode of supramolecular catalysts, [8,9,[17][18][19][20] although things may have changed in the last two years. [21][22][23][24] The systems are intrinsically challenging for computational chemistry: a large number of conformers, complicated reaction networks, and need for a sufficiently accurate description of weak interactions.…”

Section: Introductionmentioning

confidence: 99%

Computational Description of a Huisgen Cycloaddition Inside a Self‐Assembled Nanocapsule

2018

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Density functional theory calculations are applied to the study of a cycloaddition reaction between phenyl acetylene and phenyl azide taking place inside a self‐assembled nanoreactor derived from the coupling of two resorcinarene‐derived units. Calculations are applied to all steps in the reactivity of the system: self‐assembly, guest trapping, guest exchange, in‐core reaction, and product release. A reaction network is built, and the evolution of concentrations of a large variety of species over a range of time scales is obtained through the application of a kinetic model. The modeled behavior of the nanocapsule and its guests reproduces the experimental observations and completes our knowledge and understanding of this chemical system.

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Aromatic Bromination of N-Phenylacetamide Inside CNTs. Are CNTs Real Nanoreactors Controlling Regioselectivity and Kinetics? A QM/MM Investigation

Cited by 20 publications

References 61 publications

Enter the Tubes: Carbon Nanotube Endohedral Catalysis

Enter the Tubes: Carbon Nanotube Endohedral Catalysis

CNT‐Catalyzed Oxidative Dehydrogenation of Ethylbenzene to Styrene: DFT Calculations Disclose the Pathways

Computational Description of a Huisgen Cycloaddition Inside a Self‐Assembled Nanocapsule

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