Accurate <i>ab initio</i> potential energy surface, thermochemistry, and dynamics of the F− + CH3F SN2 and proton-abstraction reactions

Szabó, István; Telekes, Hajnalka; Czakó, Gábor

doi:10.1063/1.4922616

Cited by 38 publications

(80 citation statements)

References 41 publications

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“…However, we found that one cannot distinguish between the two mechanisms based on simply the integration time, as we did in the case of the F – + CH 3 Cl, F – + CH 3 F, and F – + CHD 2 Cl reactions. 6,35,36 Fig. 3 also shows the cross sections for the induced inversions of the CH 3 I reactant, which are not followed by a substitution resulting in an inverted reactant.…”

Section: Resultsmentioning

confidence: 99%

High-level ab initio potential energy surface and dynamics of the F⁻+ CH₃I S_N2 and proton-transfer reactions

2017

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Section: Resultsmentioning

confidence: 99%

High-level ab initio potential energy surface and dynamics of the F⁻+ CH₃I S_N2 and proton-transfer reactions

2017

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“…The noncovalent index (NCI) was also used to illustrate this S N 2 reaction in solution . S N 2 reactions in systems with different incoming and outgoing halogen atoms, and alternative mechanisms (front‐side attack, double inversion, and hydrogen abstraction) have also been investigated …”

Section: Introductionmentioning

confidence: 99%

An interacting quantum atom study of model S_N2 reactions (X^–···CH₃X, X = F, Cl, Br, and I)

2017

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The quantum chemical topology method has been used to analyze the energetic profiles in the X– + CH3X → XCH3 + X–SN2 reactions, with X = F, Cl, Br, and I. The evolution of the electron density properties at the BCPs along the reaction coordinate has been analysed. The interacting quantum atoms (IQA) method has been used to evaluate the intra‐atomic and interatomic energy variations along the reaction path. The different energetic terms have been examined by the relative energy gradient method and the ANANKE program, which enables automatic and unbiased IQA analysis. Four of the six most important IQA energy contributions were needed to reproduce the reaction barrier common to all reactions. The four reactions considered share many common characteristics but when X = F a number of particularities occur. © 2017 Wiley Periodicals, Inc.

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“… 14 , 23 Also a hydrogen-bonded prereaction complex where the anion points to a C–H bond axis of the methyl halide has been established. 24 , 25 These alternative entrance channel geometries not only change the kinematics and dynamics of the reaction producing the mechanisms mentioned above but also can lead to completely different products competing with nucleophilic substitution in these ion–molecule reactive systems, e.g. : Reaction ( 2 ) consists of a proton abstraction mechanism induced by an XH-bonded prereaction complex, whereas reaction ( 3 ) produces a dihalide anion through a halogen abstraction mechanism.…”

Section: Introductionmentioning

confidence: 99%

“… 28 , 29 Theoretical studies have focused mainly on the reaction type ( 2 ), investigating the properties of the [X–HCH 2 Y] − prereaction complex. 24 , 25 , 30 The contribution of the proton transfer channel has been shown to strongly depend on the proton affinity of the nucleophile. 21 The halogen abstraction mechanism, which produces a dihalide anion, has only seen little attention up to now.…”

Section: Introductionmentioning

confidence: 99%

Imaging Proton Transfer and Dihalide Formation Pathways in Reactions of F^– + CH₃I

et al. 2016

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Ion–molecule reactions of the type X– + CH3Y are commonly assumed to produce Y– through bimolecular nucleophilic substitution (SN2). Beyond this reaction, additional reaction products have been observed throughout the last decades and have been ascribed to different entrance channel geometries differing from the commonly assumed collinear approach. We have performed a crossed beam velocity map imaging experiment on the F– + CH3I reaction at different relative collision energies between 0.4 and 2.9 eV. We find three additional channels competing with nucleophilic substitution at high energies. Experimental branching ratios and angle- and energy differential cross sections are presented for each product channel. The proton transfer product CH2I– is the main reaction channel, which competes with nucleophilic substitution up to 2.9 eV relative collision energy. At this level, the second additional channel, the formation of IF– via halogen abstraction, becomes more efficient. In addition, we present the first evidence for an [FHI]− product ion. This [FHI]− product ion is present only for a narrow range of collision energies, indicating possible dissociation at high energies. All three products show a similar trend with respect to their velocity- and scattering angle distributions, with isotropic scattering and forward scattering of the product ions occurring at low and high energies, respectively. Reactions leading to all three reaction channels present a considerable amount of energy partitioning in product internal excitation. The internally excited fraction shows a collision energy dependence only for CH2I–. A similar trend is observed for the isoelectronic OH– + CH3I system. The comparison of our experimental data at 1.55 eV collision energy with a recent theoretical calculation for the same system shows a slightly higher fraction of internal excitation than predicted, which is, however, compatible within the experimental accuracy.

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Accurate ab initio potential energy surface, thermochemistry, and dynamics of the F− + CH3F SN2 and proton-abstraction reactions

Cited by 38 publications

References 41 publications

High-level ab initio potential energy surface and dynamics of the F⁻+ CH₃I S_N2 and proton-transfer reactions

High-level ab initio potential energy surface and dynamics of the F⁻+ CH₃I S_N2 and proton-transfer reactions

An interacting quantum atom study of model S_N2 reactions (X^–···CH₃X, X = F, Cl, Br, and I)

Imaging Proton Transfer and Dihalide Formation Pathways in Reactions of F^– + CH₃I

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Accurate ab initio potential energy surface, thermochemistry, and dynamics of the F− + CH3F SN2 and proton-abstraction reactions

Cited by 38 publications

References 41 publications

High-level ab initio potential energy surface and dynamics of the F−+ CH3I SN2 and proton-transfer reactions

High-level ab initio potential energy surface and dynamics of the F−+ CH3I SN2 and proton-transfer reactions

An interacting quantum atom study of model SN2 reactions (X–···CH3X, X = F, Cl, Br, and I)

Imaging Proton Transfer and Dihalide Formation Pathways in Reactions of F– + CH3I

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High-level ab initio potential energy surface and dynamics of the F⁻+ CH₃I S_N2 and proton-transfer reactions

High-level ab initio potential energy surface and dynamics of the F⁻+ CH₃I S_N2 and proton-transfer reactions

An interacting quantum atom study of model S_N2 reactions (X^–···CH₃X, X = F, Cl, Br, and I)

Imaging Proton Transfer and Dihalide Formation Pathways in Reactions of F^– + CH₃I