Low-energy electron collisions with ethane

Bettega, M. H. F.; Costa, Romarly F. da; Lima, Margareth Guimarães

doi:10.1590/s0103-97332009000100013

Cited by 5 publications

(12 citation statements)

References 20 publications

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“…However, the differential cross sections (DCSs) of the straight-chain molecules, namely ethanol, n-propanol, and n-butanol, show an f -wave scattering pattern between 5 to 10 eV, while branched systems such as isobutanol, t-butanol, and 2-butanol show a d-wave pattern. Similar behavior was also seen in alkanes [4][5][6][7][8][9][10][11][12]. These results suggest that the DCS of isopropanol (propan-2-ol or isopropyl alcohol), the branched isomer of C 3 H 7 OH, should also exhibit a d-wave pattern.…”

Section: Introductionsupporting

confidence: 67%

Collisions of low-energy electrons with isopropanol

et al. 2011

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We report measured and calculated cross sections for elastic scattering of low-energy electrons by isopropanol (propan-2-ol). The experimental data were obtained using the relative flow technique with helium as the standard gas and a thin aperture as the collimating target gas source, which permits use of this method without the restrictions imposed by the relative flow pressure conditions on helium and the unknown gas. The differential cross sections were measured at energies of 1.5, 2, 3, 5, 6, 8, 10, 15, 20, and 30 eV and for scattering angles from 10 • to 130 • . The cross sections were computed over the same energy range employing the Schwinger multichannel method in the static-exchange plus polarization approximation. Agreement between theory and experiment is very good. The present data are compared with previously calculated and measured results for n-propanol, the other isomer of C 3 H 7 OH. Although the integral and momentum transfer cross sections for the isomers are very similar, the differential cross sections show a strong isomeric effect: In contrast to the f -wave behavior seen in scattering by n-propanol, d-wave behavior is observed in the cross sections of isopropanol. These results corroborate our previous observations in electron collisions with isomers of C 4 H 9 OH.

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Section: Introductionsupporting

confidence: 67%

Collisions of low-energy electrons with isopropanol

et al. 2011

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“…Ignition and reaction chemistry involving excitation, dissociation, and ionization of these molecules in combustion (plasma) processes in automobile engines [3] is governed or catalyzed by energetic electron scattering from these fuel species in the energy region which ranges from 0.1 eV to high energies (>100 eV), but with a maximum around 10 eV [4]. Whereas there exist electron impact data on methane [5][6][7], ethane [8,9], propane [10][11][12], and butane [13], and in references cited within these, there is lack of electron collision data for pentane. The few data available for pentane are those by Freeman et al [14] of total electron cross sections determined from the mobility of electrons in liquid pentane at the energies of 0.1 to 0.5 eV using a time-of-flight method and those by Kimura et al [15] of gaseous pentane of total cross sections for this target.…”

Section: Introductionmentioning

confidence: 99%

Differential elastic electron scattering by pentane

et al. 2015

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We report measurements and calculations of the differential cross sections for elastic scattering of low-energy electrons by pentane, C 5 H 12 . The incident energies measured are at 1, 1.5, 2, 3, 5, 10, 15, 20, 30, 50, and 100 eV, and the calculations covered energies up to 100 eV. The range of experimental scattering angles is from 5°to 130°. We compare our experimental and theoretical values to each other and to available experimental and theoretical data for linear n-alkanes.

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“…Figure 12 and Figure 13 present the calculations for the TCS, TICS, IECS, INCS, MTCS, and VCS for

–

scattering in the energy range

1 eV–1 MeV using the IAM and IAMS in the framework of the OM potential. The calculated scattering observables for electron scattering were compared with the experimental measurements of Floeder et al [ 19 ], Sueoka and Mori [ 21 ], Nishimura and Tawara [ 25 ], Ariyasinghe and Powers [ 29 ], Szmytkowski and Krzysztofowicz [ 26 ], Grill et al [ 35 ], Duric et al [ 36 ], Tian and Vidal [ 37 ], Schram et al [ 38 ], Chatham et al [ 69 ], Nishimura and Tawara [ 39 ], Rawat et al [ 23 ], Tanaka et al [ 22 ], and Shishikura et al [ 40 ]; and the theoretical calculations of Joshipura and Vindkumar [ 42 ], Jin-Feng et al [ 43 ], Vinodkumar et al [ 44 ], Rawat et al [ 23 ], Hwang et al [ 45 ], Mayol and Salvat [ 70 ], Bettega et al [ 33 , 41 ], Sun et al [ 32 ], and Hayashi [ 46 ]. As is evident from Figure 12 a,c–f, the calculated TCS, IECS, INCS, MTCS, and VCS using the IAM overestimate the experimental data, particularly at lower electron energies than those using the IAMS and other studies.…”

Section: Resultsmentioning

confidence: 99%

“… DCS

for the elastic scattering of electrons from

at energies of 17.5, 20, 40, 60, 80, and 100 eV. Theoretical works: IAM, IAMS, Rawat et al [ 23 ] and Bettega et al [ 41 ]; Experimental works: Curry et al [ 20 ], Tanaka et al [ 22 ], Rawat et al [ 23 ], and Fink et al [ 16 ]. …”

Section: Figurementioning

confidence: 99%

“…Bettega et al [ 33 ] theoretically investigated the DCS and IECS for electron scattering from

, and

from 5 to 30 eV using an ab initio Schwinger multichannel method (SMC) with pseudopotentials. In another work, Bettega et al [ 41 ] calculated the elastic DCS and IECS for low-energy electron scattering up to 12 eV employing the same SMC including the polarization effect with the pseudopotential. The TCS and inelastic cross-sections (INCS) for

–

scattering were theoretically studied by Joshipura and Vinodkumar [ 42 ] at collision energies

= 50–5000 eV using optical model potential (OPM) with the additivity rule (AR), wherein the molecular cross-section was an incoherent sum of the cross-sections of the constituent atoms.…”

Section: Introductionmentioning

confidence: 99%

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Scattering of e± by C2H6 Molecule over a Wide Range of Energy: A Theoretical Investigation

et al. 2023

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The present work reports the theoretical investigation of the scattering of electrons and positrons by the ethane (C2H6) molecule over the energy range 1 eV–1 MeV. The investigation was carried out by taking into account the screening correction arising from a semiclassical analysis of the atomic geometrical overlapping of the scattering observables calculated in the independent atom approximation. The study is presented through the calculations of a broad spectrum of observable quantities, namely differential, integrated elastic, momentum transfer, viscosity, inelastic, grand total, and total ionization cross-sections and the Sherman functions. A comparative study was carried out between scattering observables for electron impact with those for positron impact to exhibit the similarity and dissimilarity arising out of the difference of the collisions of impinging projectiles with the target. Partial-wave decomposition of the scattering states within the Dirac relativistic framework employing a free-atom complex optical model potential was used to calculate the corresponding observable quantities of the constituent atoms. The results, calculated using our recipe, were compared with the experimental and theoretical works available in the literature. The Sherman function for a e±−C2H6 scattering system is presented for the first time in the literature. The addition of the screening correction to the independent atom approximation method was found to substantially reduce the scattering cross-sections, particularly at forward angles for lower incident energies.

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Low-energy electron collisions with ethane

Cited by 5 publications

References 20 publications

Collisions of low-energy electrons with isopropanol

Collisions of low-energy electrons with isopropanol

Differential elastic electron scattering by pentane

Scattering of e± by C2H6 Molecule over a Wide Range of Energy: A Theoretical Investigation

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