The Impact of Resonance Stabilization on the Intramolecular Hydrogen‐Atom Shift Reactions of Hydrocarbon Radicals

Wang, Kun; Villano, Stephanie M.; Dean, Anthony M.

doi:10.1002/cphc.201500396

Cited by 21 publications

(10 citation statements)

References 31 publications

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“…Thus, the CPO-3 radical is more reactive and in the absence of other interfering reactions will primarily decompose by elimination of carbon monoxide to yield the 3-buten-1-yl radical, H 2 CCH–CH 2 ĊH 2 . Subsequent reactions of this radical, such as a 1,2-hydrogen shift to form an allylic system, , have been thoroughly explored in recent times by Dean et al and Miyoshi …”

Section: Resultsmentioning

confidence: 99%

“…3 , have been thoroughly explored in recent times by Dean et al 39 and Miyoshi. 40 We note that species corresponding to C 4 H 7 + were detected by mass spectrometry in the very recent flow tube experiments 10 of Cl • + CPO at 550−650 K both in the presence and in the absence of O 2 , which is supporting evidence of the essential correctness of the ring-opening and β-scission routes calculated here.…”

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confidence: 99%

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Toward the Development of a Fundamentally Based Chemical Model for Cyclopentanone: High-Pressure-Limit Rate Constants for H Atom Abstraction and Fuel Radical Decomposition

et al. 2016

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including 2-and 3-oxo-cyclopentyl radicals which are in reasonable agreement with 6 the literature. These radicals can be formed via H-atom abstraction reactions byḢ 7 andÖ atoms, andȮH, HȮ 2 , andĊH 3 radicals, the rate constants of which have been 8 calculated. Abstraction from the β hydrogen atom is the dominant process whenȮH 9 is involved but the reverse holds true for HȮ 2 radicals. The subsequent β-scission of 10 the radicals formed are also determined and it is shown that recent tunable VUV pho-11 toionization mass spectrometry experiments can be interpreted in this light. The bulk 12

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Toward the Development of a Fundamentally Based Chemical Model for Cyclopentanone: High-Pressure-Limit Rate Constants for H Atom Abstraction and Fuel Radical Decomposition

et al. 2016

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“…H-atom migration due to radicals on alkyl chains has been studied computationally and experimentally in hydrocarbon combustion and pyrolysis − and in polymer production and degradation processes. − Here, the formation of additional short branches in low-density polyethylene (PE) attributed to H-atom migration is the best known example, , but H-atom migration has also been proposed during oxidation of PP . The general scheme of this class of reactions, also known under the name “mid-chain radical migration,” , is shown in Figure .…”

Section: Introductionmentioning

confidence: 99%

Tacticity Changes during Controlled Degradation of Polypropylene

et al. 2021

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The controlled reactive degradation of polypropylene (CPP) in a twin-screw extruder has been investigated from the perspective of tacticity. CPP is initiated by the decomposition of a peroxide producing radicals that abstract hydrogen from the chain backbone creating tertiary radicals. Since C atoms with tertiary radicals have no longer sp3 configurations, they temporarily lose their stereospecificity. The C atoms resume stereospecificity upon termination, whereby methyl groups may assume a different orientation than before, causing a tacticity change. Degradation experiments in a twin-screw extruder of isotactic PP samples have been performed and tacticity changes are observed by C-13 NMR measurements revealing a decrease of isotactic mmmm pentads and increases of pentads with racemic sequence pairs. Statistical analysis of NMR data shows that the change of tacticity is nonrandom, i.e., units on the chain backbone are more likely to change orientation if they are close together. We attribute the nonrandomness to isomerization reactions, where through cyclic intermediates, a radical from one tertiary C carbon is transferred to anotherradical chain walking. To validate this chain-walking hypothesis, a kinetic Monte Carlo simulation algorithm has been developed that predicts the change of the pentad distribution from the reactions taking place: initiation of tertiary radicals, transfer to polymer, chain walking, and termination by disproportionation. PP chains simulated consist of around 109 units with orientations of methyl groups inferred from the pentad distribution measured by NMR. Simulated pentad changes are compared to those measured from NMR, which reveal a relatively high racemic content. kMC simulations show that this can only be explained by assuming chain walking. Also, this isomerization via ring-shaped intermediates influences the patterns of changes in pentad distribution. These findings demonstrate that molecular weight changes are accompanied by tacticity changes. The kMC models confirmed by NMR data show that these tacticity changes are clustered locally along PP chains and that tacticity changes happen within the length scale of individual pentads. Chain-walking isomerization as a main cause of the tacticity changes is supported by predictions from the kMC model.

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“…Similar schemes were also applied by Ghent, ,− Kang , and other − groups, which used ab initio group contribution method for activation energies for radical additions. Alternatively, a set of rate rules based on the high-level calculations of the model systems, which can be applied to a range of analogous reactions, was proposed by Dean and co-workers. − Systematic, based on high level CBS-Q, G2, and G4 composite computational methods, and study of H migrations in hydrocarbons, including cyclic species, were reported by Davis et al − …”

Section: Introductionmentioning

confidence: 99%

Performance of First-Principles-Based Reaction Class Transition State Theory

2016

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Performance of the Reaction Class Transition State Theory (RC-TST) for prediction of rates constants of elementary reactions is examined using data from its previous applications to a number of different reaction classes. The RC-TST theory is taking advantage of the common structure denominator of all reactions in a given family combined with structure activity relationships to provide a rigorous theoretical framework to obtain rate expression of any reaction within a reaction class in a simple and cost-effective manner. This opens the possibility for integrating this methodology with an automated mechanism generator for "on-the-fly" generation of accurate kinetic models of complex reacting systems.

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The Impact of Resonance Stabilization on the Intramolecular Hydrogen‐Atom Shift Reactions of Hydrocarbon Radicals

Cited by 21 publications

References 31 publications

Toward the Development of a Fundamentally Based Chemical Model for Cyclopentanone: High-Pressure-Limit Rate Constants for H Atom Abstraction and Fuel Radical Decomposition

Toward the Development of a Fundamentally Based Chemical Model for Cyclopentanone: High-Pressure-Limit Rate Constants for H Atom Abstraction and Fuel Radical Decomposition

Tacticity Changes during Controlled Degradation of Polypropylene

Performance of First-Principles-Based Reaction Class Transition State Theory

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