Dissociative photoionization of CH3C(O)CH2 to C2H5+

Alligood, Bridget W.; Womack, Caroline C.; Brynteson, Matthew D.; Butler, Laurie J.

doi:10.1016/j.ijms.2011.03.012

Cited by 7 publications

(12 citation statements)

References 25 publications

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“…We assign the latter to the ethyl cation (C 2 H 5 + ), which may be formed through the bond cleavage between the ethyl and the CO groups from the propanoyl cation (m/z 57), as in reaction 11. A similar mechanism for the formation of this cation was also proposed by Alligood et al 10…”

Section: H Ocl C H O Clmentioning

confidence: 88%

“…Foffani et al have reported some dissociation channels from this molecule using a magnetic sector mass spectrometer and a Nier-type ion source. Other reports have studied dissociation reactions from chloroacetone at some predefined energies. − Briefly, Alligood et al − have studied the bond photofission of the chloroacetone neutral molecule at 193 nm by means of crossed-laser molecular beam scattering and velocity map imaging experiments and reported that the C–Cl bond fission corresponds to the most relevant dissociation channel of the molecule, as well as studies on the dissociation of the CH 3 COCH 2 radical into the ketene and methyl products and its dissociative photoionization to C 2 H 5 + and CO species. Waschewsky et al and Kitchen et al investigated the photodissociation of the chloroacetone at 308 nm by employing the crossed-laser molecular beam scattering technique and indicated that the C–Cl bond cleavage is favored in the more energetic trans conformer of the neutral molecule and is therefore temperature dependent.…”

Section: Introductionmentioning

confidence: 99%

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VUV-Induced Photodissociation of the Chloroacetone Molecule Studied by Photoelectron-Photoion Coincidence Spectroscopy

Rogério

Cavasso-Filho

Lago

2021

J. Am. Soc. Mass Spectrom.

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The dissociative photoionization dynamics of the chloroacetone molecule (C3H5OCl) in the gas phase, induced by vacuum ultraviolet (VUV) synchrotron radiation in the range from 10.85 to 21.50 eV, has been investigated by using time-of-flight mass spectrometry in the photoelectron-photoion coincidence mode. The appearance energies for the most relevant cation fragments produced in this energy range have been analyzed, and the fragmentation pathways leading to the formation of the cation species have been proposed and discussed. The mass spectra show that the most dominant VUV photodissociation cation product appears at m/z 43 and has been assigned to the C2H3O+ species. Enthalpies of formation (Δf H°0K) for the neutral chloroacetone molecule and its molecular cation have been derived and correspond to −207.8 ± 5.8 kJ/mol and 755.1 ± 6.8 kJ/mol, respectively. In addition to the spectral analysis, the structural and energetic parameters for the cations produced have also been examined on the basis of high-level quantum chemical numerical calculations.

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Section: H Ocl C H O Clmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 99%

VUV-Induced Photodissociation of the Chloroacetone Molecule Studied by Photoelectron-Photoion Coincidence Spectroscopy

Rogério

Cavasso-Filho

Lago

2021

J. Am. Soc. Mass Spectrom.

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“…Although stable radicals were not present at parent m/e = 57 (CH 3 C(O)CH 2 + ) in either the scattering or imaging apparatuses, we were able to confirm the validity of the results obtained with this impulsive model by comparing with the signal observed at daughter mass-to-charge ratios -the signal observed at m/e = 42 (COCH 2 + ) and at m/e = 15 (CH 3 + ) in the scattering apparatus with 200 eV electron bombardment ionization, 7 and with data taken at m/e = 29 (C 2 H 5 + ) in the imaging apparatus with 10.5 eV photoionization. 14 The results from this impulsive model revealed that roughly 77.8% of the CH 3 C(O)CH 2 radicals that were formed from primary C-Cl bond photofission were stable to subsequent dissociation to CH 3 and ketene. The other 22.2% were formed with vibrational energies above the dissociation barrier out to CH 3 + ketene; those products were detected at m/e = 15 (CH 3 + ) and at m/e = 42 (COCH 2 + ), respectively.…”

Section: A Model For Dissociation Of Unstable Radicalsmentioning

confidence: 94%

“…The velocity map imaging apparatus used in this work has been described previously; [9][10][11][12][13] the relevant experimental conditions have also been detailed in our previous work on this system. 7,14 We expand the molecular beam, composed of the vapor pressure of chloroacetone seeded in He to a total backing pressure of 400 Torr, through a pulsed valve; we heat the nozzle, which has a 0.8 mm diameter, to 80 • C. After passing through a skimmer, the molecules are photodissociated with a vertically polarized 193.3 nm beam.…”

Section: A Experimental Methods --Imaging Apparatusmentioning

confidence: 99%

“…The experimental details relevant to this system, both experimental conditions and defined apparatus parameters, have been described previously. 7,14 We expand the molecular beam, composed of chloroacetone seeded in He to a total stagnation pressure of 400 Torr, through a continuous (not pulsed) nozzle. The nozzle has a 0.15 mm diameter, and we heat it to 180 • C. The molecular beam passes through two skimmers before it enters the main chamber, where it intersects the output of a 193.3 nm excimer laser.…”

Section: B Experimental Methods -Scattering Apparatusmentioning

confidence: 99%

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Analyzing velocity map images to distinguish the primary methyl photofragments from those produced upon C–Cl bond photofission in chloroacetone at 193 nm

Alligood

Straus

Butler

2011

The Journal of Chemical Physics

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We use a combination of crossed laser-molecular beam scattering experiments and velocity map imaging experiments to investigate the three primary photodissociation channels of chloroacetone at 193 nm: C-Cl bond photofission yielding CH(3)C(O)CH(2) radicals, C-C bond photofission yielding CH(3)CO and CH(2)Cl products, and C-CH(3) bond photofission resulting in CH(3) and C(O)CH(2)Cl products. Improved analysis of data previously reported by our group quantitatively identifies the contribution of this latter photodissociation channel. We introduce a forward convolution procedure to identify the portion of the signal, derived from the methyl image, which results from a two-step process in which C-Cl bond photofission is followed by the dissociation of the vibrationally excited CH(3)C(O)CH(2) radicals to CH(3) + COCH(2). Subtracting this from the total methyl signal identifies the methyl photofragments that result from the CH(3) + C(O)CH(2)Cl photofission channel. We find that about 89% of the chloroacetone molecules undergo C-Cl bond photofission to yield CH(3)C(O)CH(2) and Cl products; approximately 8% result in C-C bond photofission to yield CH(3)CO and CH(2)Cl products, and the remaining 2.6% undergo C-CH(3) bond photofission to yield CH(3) and C(O)CH(2)Cl products.

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Photoproduct Channels from BrCD₂CD₂OH at 193 nm and the HDO + Vinyl Products from the CD₂CD₂OH Radical Intermediate

et al. 2012

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We present the results of our product branching studies of the OH + C 2 D 4 reaction, beginning at the CD 2 CD 2 OH radical intermediate of the reaction, which is generated by the photodissociation of the precursor molecule BrCD 2 CD 2 OH at 193 nm. Using a crossed laser-molecular beam scattering apparatus with tunable photoionization detection, and a velocity map imaging apparatus with VUV photoionization, we detect the products of the major primary photodissociation channel (Br and CD 2 CD 2 OH), and of the secondary dissociation of vibrationally excited CD 2 CD 2 OH radicals (OH, C 2 D 4 / CD 2 O, C 2 D 3 , CD 2 H, and CD 2 CDOH). We also characterize two additional photodissociation channels, which generate HBr + CD 2 CD 2 O and DBr + CD 2 CDOH, and measure the branching ratio between the C−Br bond fission, HBr elimination, and DBr elimination primary photodissociation channels as 0.99:0.0064:0.0046. The velocity distribution of the signal at m/e = 30 upon 10.5 eV photoionization allows us to identify the signal from the vinyl (C 2 D 3 ) product, assigned to a frustrated dissociation toward OH + ethene followed by D-atom abstraction. The relative amount of vinyl and Br atom signal shows the quantum yield of this HDO + C 2 D 3 product channel is reduced by a factor of 0.77 ± 0.33 from that measured for the undeuterated system. However, because the vibrational energy distribution of the deuterated radicals is lower than that of the undeuterated radicals, the observed reduction in the water + vinyl product quantum yield likely reflects the smaller fraction of radicals that dissociate in the deuterated system, not the effect of quantum tunneling. We compare these results to predictions from statistical transition state theory and prior classical trajectory calculations on the OH + ethene potential energy surface that evidenced a roaming channel to produce water + vinyl products and consider how the branching to the water + vinyl channel might be sensitive to the angular momentum of the β-hydroxyethyl radicals.

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Dissociative photoionization of CH3C(O)CH2 to C2H5+

Cited by 7 publications

References 25 publications

VUV-Induced Photodissociation of the Chloroacetone Molecule Studied by Photoelectron-Photoion Coincidence Spectroscopy

VUV-Induced Photodissociation of the Chloroacetone Molecule Studied by Photoelectron-Photoion Coincidence Spectroscopy

Analyzing velocity map images to distinguish the primary methyl photofragments from those produced upon C–Cl bond photofission in chloroacetone at 193 nm

Photoproduct Channels from BrCD₂CD₂OH at 193 nm and the HDO + Vinyl Products from the CD₂CD₂OH Radical Intermediate

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Dissociative photoionization of CH3C(O)CH2 to C2H5+

Cited by 7 publications

References 25 publications

VUV-Induced Photodissociation of the Chloroacetone Molecule Studied by Photoelectron-Photoion Coincidence Spectroscopy

VUV-Induced Photodissociation of the Chloroacetone Molecule Studied by Photoelectron-Photoion Coincidence Spectroscopy

Analyzing velocity map images to distinguish the primary methyl photofragments from those produced upon C–Cl bond photofission in chloroacetone at 193 nm

Photoproduct Channels from BrCD2CD2OH at 193 nm and the HDO + Vinyl Products from the CD2CD2OH Radical Intermediate

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Product

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About

Photoproduct Channels from BrCD₂CD₂OH at 193 nm and the HDO + Vinyl Products from the CD₂CD₂OH Radical Intermediate