Dissociative Photodetachment Dynamics of the OH–(C2H4) Anion Complex

Benitez, Yanice; Parsons, Austin J.; Lunny, Katharine G.; Continetti, Robert E.

doi:10.1021/acs.jpca.1c01835

Cited by 3 publications

(5 citation statements)

References 48 publications

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“…In summary, we have found that photodetachment of ground states. This interpretation of the data is similar to previous studies of hydroxyl radical reactions 27,36 and the reaction of F + CH 3 OH. 28 Water stretch excitation in photodetachment was found to promote dissociation of the nascent complex, while bend excitation was seen predominantly in long-lived neutral complexes.…”

supporting

confidence: 91%

“…In summary, we have found that photodetachment of CH 3 O – (H 2 O) at a photon energy of 3.20 eV yields both direct and resonance-mediated mechanisms for the formation of vibrationally excited H 2 O + CH 3 O + e – products in addition to a significant yield of H 2 O + CH 3 O + e – in the vibrational ground states. This interpretation of the data is similar to previous studies of hydroxyl radical reactions , and the reaction of F + CH 3 OH . Water stretch excitation in photodetachment was found to promote dissociation of the nascent complex, while bend excitation was seen predominantly in long-lived neutral complexes.…”

supporting

confidence: 89%

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Probing the Exit Channel of the OH + CH₃OH → H₂O + CH₃O Reaction by Photodetachment of CH₃O^–(H₂O)

Benitez

Nguyen

Parsons

et al. 2021

J. Phys. Chem. Lett.

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Transition state dynamics of bimolecular reactions can be probed by photodetachment of a precursor anion when the Franck–Condon region of the corresponding neutral potential energy surface is near a saddle point. In this study, photodetachment of anions at m/z = 49 enabled investigation of the exit channel of the OH + CH3OH → H2O + CH3O reaction using photoelectron-photofragment coincidence spectroscopy. High-level coupled-cluster calculations of the stationary points on the anion surface show that the methoxide–water cluster CH3O–(H2O) is the stable minimum on the anion surface. Photodetachment at a 3.20 eV photon energy leads to long-lived H2O(CH3O) complexes and H2O + CH3O products consistent with both direct dissociative photodetachment and resonance mediated processes on the neutral surface. The partitioning of total kinetic energy in the system indicates that water stretch and bend excitation is induced in dissociative photodetachment and evidence for long-lived complexes consistent with vibrational Feshbach resonances is reported.

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supporting

confidence: 91%

supporting

confidence: 89%

Probing the Exit Channel of the OH + CH₃OH → H₂O + CH₃O Reaction by Photodetachment of CH₃O^–(H₂O)

Benitez

Nguyen

Parsons

et al. 2021

J. Phys. Chem. Lett.

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“…Their study established that CH 4 , when in the OH – ·CH 4 complex, is slightly distorted relative to isolated CH 4 , since vibrational excitation of CH 4 was evident in the photoelectron spectrum. A similar study was conducted on the OH – ·C 2 H 4 ion–molecule complex . Their results provided insight into the dynamics of the entrance channel of the abstraction reaction.…”

Section: Neutral Atmospheric Reaction Complexes Studied By Detachment...mentioning

confidence: 99%

“…A similar study was conducted on the OH − •C 2 H 4 ion−molecule complex. 136 Their results provided insight into the dynamics of the entrance channel of the abstraction reaction.…”

Section: Neutral Atmospheric Reaction Complexes Studied By Detachment...mentioning

confidence: 99%

Probing Anion–Molecule Complexes of Atmospheric Relevance Using Anion Photoelectron Detachment Spectroscopy

Jarrold

2022

ACS Phys. Chem Au

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Bimolecular reaction and collision complexes that drive atmospheric chemistry and contribute to the absorption of solar radiation are fleeting and therefore inherently challenging to study experimentally. Furthermore, primary anions in the troposphere are short lived because of a complicated web of reactions and complex formation they undergo, making details of their early fate elusive. In this perspective, the experimental approach of photodetaching mass-selected anion–molecule complexes or complex anions, which prepares neutrals in various vibronic states, is surveyed. Specifically, the application of anion photoelectron spectroscopy along with photoelectron–photofragment coincidence spectroscopy toward the study of collision complexes, complex anions in which a partial covalent bond is formed, and radical bimolecular reaction complexes, with relevance in tropospheric chemistry, will be highlighted.

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“…Kinetic experiments have been performed to obtain information on the rate coefficients and their dependence on temperature and pressure, − and kinetic and photochemical investigations to derive product branching fractions have also been reported. − Additionally, theoretical calculations have been carried out to derive the relevant potential energy surface (PES) and to obtain a theoretical estimate of the rate coefficients through high-level ab initio electronic structure and kinetic (statistical) calculations. − According to these studies, the OH + C 2 H 4 reaction can proceed through two different mechanisms, that is, either by the H-abstraction mechanism, leading to the formation of a water molecule and the vinyl radical (C 2 H 3 ), or by the addition mechanism of the OH radical to the CC double bond of ethylene. While the direct abstraction process exhibits a sizeable entrance energy barrier, the addition process appears to be barrierless and is characterized by the initial formation of a pre-reactive van der Waals complex, which leads to the formation of the C 2 H 4 OH (2-hydroxyethyl) covalently bound radical intermediate through a submerged barrier.…”

Section: Introductionmentioning

confidence: 99%

OH(²Π) + C₂H₄ Reaction: A Combined Crossed Molecular Beam and Theoretical Study

et al. 2023

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The reaction between the ground-state hydroxyl radical, OH(2Π), and ethylene, C2H4, has been investigated under single-collision conditions by the crossed molecular beam scattering technique with mass-spectrometric detection and time-of-flight analysis at the collision energy of 50.4 kJ/mol. Electronic structure calculations of the underlying potential energy surface (PES) and statistical Rice–Ramsperger–Kassel–Marcus (RRKM) calculations of product branching fractions on the derived PES for the addition pathway have been performed. The theoretical results indicate a temperature-dependent competition between the anti-/syn-CH2CHOH (vinyl alcohol) + H, CH3CHO (acetaldehyde) + H, and H2CO (formaldehyde) + CH3 product channels. The yield of the H-abstraction channel could not be quantified with the employed methods. The RRKM results predict that under our experimental conditions, the anti- and syn-CH2CHOH + H product channels account for 38% (in similar amounts) of the addition mechanism yield, the H2CO + CH3 channel for ∼58%, while the CH3CHO + H channel is formed in negligible amount (<4%). The implications for combustion and astrochemical environments are discussed.

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Dissociative Photodetachment Dynamics of the OH^–(C₂H₄) Anion Complex

Cited by 3 publications

References 48 publications

Probing the Exit Channel of the OH + CH₃OH → H₂O + CH₃O Reaction by Photodetachment of CH₃O^–(H₂O)

Probing the Exit Channel of the OH + CH₃OH → H₂O + CH₃O Reaction by Photodetachment of CH₃O^–(H₂O)

Probing Anion–Molecule Complexes of Atmospheric Relevance Using Anion Photoelectron Detachment Spectroscopy

OH(²Π) + C₂H₄ Reaction: A Combined Crossed Molecular Beam and Theoretical Study

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Dissociative Photodetachment Dynamics of the OH–(C2H4) Anion Complex

Cited by 3 publications

References 48 publications

Probing the Exit Channel of the OH + CH3OH → H2O + CH3O Reaction by Photodetachment of CH3O–(H2O)

Probing the Exit Channel of the OH + CH3OH → H2O + CH3O Reaction by Photodetachment of CH3O–(H2O)

Probing Anion–Molecule Complexes of Atmospheric Relevance Using Anion Photoelectron Detachment Spectroscopy

OH(2Π) + C2H4 Reaction: A Combined Crossed Molecular Beam and Theoretical Study

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Dissociative Photodetachment Dynamics of the OH^–(C₂H₄) Anion Complex

Probing the Exit Channel of the OH + CH₃OH → H₂O + CH₃O Reaction by Photodetachment of CH₃O^–(H₂O)

Probing the Exit Channel of the OH + CH₃OH → H₂O + CH₃O Reaction by Photodetachment of CH₃O^–(H₂O)

OH(²Π) + C₂H₄ Reaction: A Combined Crossed Molecular Beam and Theoretical Study