Electron collisions with ammonia and formamide in the low- and intermediate-energy ranges

Homem, M. G. P.; Iga, I.; Souza, Gabriel L. C. de; Zanelato, A. I.; Machado, L. E.; Ferraz, J. R.; Santos, A. S.; Brescansin, L. M.; Lucchese, Robert R.; Lee, M.-T.

doi:10.1103/physreva.90.062704

Cited by 24 publications

(61 citation statements)

References 61 publications

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“…As for acetaldehyde, TCS reported by Szmytkowski [13] for acetone also did not present evidence of the π * shape resonance at low incident energies. One possible reason is that both acetaldehyde and acetone are strongly polar targets; therefore the π * shape resonance feature might be masked by the intense dipole-scattering background, as seen in our previous work on formamide [7]. In order to clarify this fact, the present paper reports a theoretical investigation on e − -acetone scattering.…”

Section: Introductionmentioning

confidence: 79%

“…From a theoretical point of view, electron-assisted processes involving the organic molecules with the carbonyl group in their structures may support a shape resonance due to the existence of an empty π * orbital that may trap electrons to form metastable states. Such resonances were in fact identified in the theoretical studies of low-energy electron collisions with formaldehyde [1][2][3], formic acid [4,5], and, more recently, acetaldehyde [6] and formamide [7]. Experimentally, such resonances were seen in studies involving electron interaction with carbonyl-containing compounds.…”

Section: Introductionmentioning

confidence: 90%

“…In our calculation, the dynamics of the projectile-target interaction is represented by a molecular complex optical potential (MCOP) at the static-exchangepolarization plus absorption (SEPA) level of approximation. This model has already been applied by our group to study electron collisions with other carbonyl-containing molecules, e.g., formaldehyde [3] and formamide [7]. Also, due to the lack of experimental DCS for this target, we performed measurements of this physical quantity in the 30-800 eV range using the relative-flow technique (RFT).…”

Section: Introductionmentioning

confidence: 99%

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Theoretical and experimental investigation of electron collisions with acetone

et al. 2015

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We report a joint theoretical-experimental investigation on elastic electron scattering by acetone in the low-and intermediate-energy regions. More specifically, experimental differential, integral, and momentum-transfer cross sections are given in the 30-800 eV and 10 • -120 • ranges. Theoretical cross sections are reported in the 1-500 eV interval. The experimental differential cross sections were determined using a crossed electron-beam-molecularbeam geometry, whereas the absolute values of the cross sections were obtained using the relative-flow technique. Theoretically, a complex optical potential derived from a Hartree-Fock molecular wave function was used to represent the collision dynamics, and a single-center expansion method combined with the Padé approximant technique was used to solve the scattering equations. Our experimental cross-section data are in generally good agreement with the present calculated data. Also, our calculated grand-total and total absorption cross sections are in good agreement with the experimental results reported in the literature. Nevertheless, our calculations have revealed a strong shape resonance in the 2 B 2 scattering channel not clearly seen in the experimental results. Possible reasons for this fact are also discussed.

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Section: Introductionmentioning

confidence: 79%

Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

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Theoretical and experimental investigation of electron collisions with acetone

et al. 2015

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“…For example, elastic electron scattering from FA was studied in Refs. [16][17][18][19][20][21] and inelastic electron scattering in [22]. Wang and Tian reported computational results for inelastic electron scattering as well [20].…”

Section: Introductionmentioning

confidence: 99%

Electron ionization of clusters containing the formamide molecule

et al. 2021

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Studies on electron interactions with formamide (FA) clusters promote scientific interest as a model system to understand phenomena relevant to astrophysical, prebiotic, and radiobiological processes. In this work, mass spectrometric detection of cationic species for both small bare and microhydrated formamide clusters was performed at an electron ionization of 70 eV. Furthermore, a comparative analysis of the cluster spectra with the literature-reported gas-phase spectra is presented and discussed, revealing different reaction channels affected by the cluster environment. This study is essential in developing our understanding of both low-energy electron phenomena in clusters that can bridge the complexity gap between gas and realistic systems and the effect of hydration on electron-induced processes.

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“…Electron scattering from formamide has been extensively studied previously over a broad range of energies [20][21][22][23]. Studies of the dissociation pathways of formamide irradiated by (vacuum) ultraviolet light [24,25] or higher energy radiation [26][27][28] have revealed chemical products of biological and technological relevance.…”

Section: Introductionmentioning

confidence: 99%

Investigating resonant low-energy electron attachment to formamide: dynamics of model peptide bond dissociation and other fragmentation channels

Panelli,

Moradmand,

Griffin

et al. 2020

Preprint

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We report experimental results on three-dimensional momentum imaging measurements of anions generated via dissociative electron attachment to gaseous formamide. From the momentum images, we analyze the angular and kinetic energy distributions for NH − 2 , O − , and H − fragments and discuss the possible electron attachment and dissociation mechanisms for multiple resonances for two ranges of incident electron energies, from 5.3 eV to 6.8 eV, and from 10.0 eV to 11.5 eV. Ab initio theoretical results for the angular distributions of the NH − 2 anion for ∼6 eV incident electrons, when compared with the experimental results, strongly suggest that one of the two resonances producing this fragment is a 2 A Feshbach resonance.

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Electron collisions with ammonia and formamide in the low- and intermediate-energy ranges

Cited by 24 publications

References 61 publications

Theoretical and experimental investigation of electron collisions with acetone

Theoretical and experimental investigation of electron collisions with acetone

Electron ionization of clusters containing the formamide molecule

Investigating resonant low-energy electron attachment to formamide: dynamics of model peptide bond dissociation and other fragmentation channels

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