Collision Strengths of Astrophysical Interest for Multiply Charged Ions

Fritzsche, S.; Jiao, Li Guang; Wang, Yuancheng; Sienkiewicz, J. E.

doi:10.3390/atoms11050080

Cited by 4 publications

(2 citation statements)

References 59 publications

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“…These measurements also show that at low impact energies, the inner-shell excitation of the 2s + 2p (and to a minor extent, the 1s) shells plays a relevant role owing to the rapid autoionization of these hole configurations. These inner-shell excitation also explains the various "jumps" in the total EII cross section in terms of the excitation thresholds and the contributions from the different shells [59]. The role of these excitation-autoionization processes is also seen in the rather large deviations of all empirical models for impact energies below and near the maximum of the total cross section.…”

mentioning

confidence: 82%

Rapid Access to Empirical Impact Ionization Cross Sections for Atoms and Ions across the Periodic Table

Fritzsche,

Jiao,

Visentin

2024

Plasma

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Electron-impact ionization (EII) processes are essential for modelling high-temperature plasma in quite different research areas, from astrophysics to material science to plasma and fusion research and in several places elsewhere. In most, if not all, of these fields, partial and total EII cross sections are required, and often for a good range of electron energies, in order to determine, for instance, the level population of ions and spectral line intensities in plasma under both local and non-local thermodynamic equilibrium conditions. To obey these needs, various kinds of semi-empirical EII cross sections have been applied in practice, often simply because of the large computational demands in dealing explicitly with two free electrons within the continuum. Here, we expand Jac, the Jena Atomic Calculator, to provide such empirical EII cross sections for (most) atoms and ions across the periodic table. Five empirical models from the recent literature have been implemented to support a simple and rapid access to the partial EII cross sections for electrons from a (partly filled) shell (nℓ)q as well as the total ionization cross sections. We here restrict ourselves to the direct part of the EII cross section, whereas the impact excitation of electrons with subsequent autoionization and the resonant electron capture with double autoionization have been left aside in this first implementation. Rapid access to the (direct) EII cross sections will help already to better understand the role of electron-impact processes in the diagnostics of fusion plasma or the interpretation of astrophysical spectra.

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mentioning

confidence: 82%

Rapid Access to Empirical Impact Ionization Cross Sections for Atoms and Ions across the Periodic Table

Fritzsche,

Jiao,

Visentin

2024

Plasma

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“…The discrepancy in the lower energy range likely arises from omitting the excitation-autoionization contributions [54][55][56] in the present model. The difference between the present computations and experiment mainly arise from autoionization contributions due to the excitation of the 5p and 5s electrons into autoionization states with thresholds (12.256 46 and 20.9515 eV for the 5p and 5s electrons, respectively [57,58]) near the corresponding ionization potentials of each orbital.…”

Section: Total Ionization Cross Section For Xementioning

confidence: 99%

Generalized binary-encounter-Bethe model for electron impact ionization of atoms

Wang,

Jiao,

Fritzsche

2024

J. Phys. B: At. Mol. Opt. Phys.

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A generalized binary-encounter-Bethe (GBEB) model is proposed to calculate the partial ionization cross sections of all shells. The present model improves the original version of Kim \textit{et al.} [Phys. Rev. A \textbf{62}, 052710 (2000)] by incorporating a physically constructed effective charge felt by the ejected electron in the empirical factor, which prevents the selection of specific factors for different shells. A generalized relativistic BEB formula is also proposed and applied to different inner shells of C, Al, Fe, Ar, Ag, Xe, Sn, Pb, and Bi atoms for impact energies from the thresholds up to $10^{6}$ keV. The present model improves the partial ionization cross sections in the low-energy region compared to other relativistic BEB models. The GBEB partial and total ionization cross sections of the Xe atom are compared with the original BEB results. The present calculations, combined with the contribution from the direct multiple ionization, show good agreement with the experimental measurements in the intermediate- and high-energy ranges. We conclude that the present GBEB model, without any fitting parameters and \textit{ad hoc} corrections, improves the BEB prediction of partial and total ionization cross sections for a good variety of atomic targets.

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Experimental study of rotational relaxation for D2(1,12) in collisions with N2

Mao,

Liu,

Habibulla

et al. 2024

The Journal of Chemical Physics

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The rotational relaxation behavior of D2(1,12) in a D2–N2 mixture was investigated using coherent anti-Stokes Raman scattering (CARS) technique. The rovibrational level v = 1 and J = 12 of D2 was selectively excited through stimulated Raman pumping while monitoring the temporal evolution of population for D2(1, J ≤ 12) molecules using time-resolved CARS spectroscopy. The results demonstrate that the rotational relaxation processes of D2(1,12) encompass both multi-quantum relaxation and continuous single-quantum relaxation. When α, the molar ratio of N2, is less than 0.5, D2(1,12) predominantly undergoes a single quantum relaxation process transition. However, when α ≥ 0.5, the multi-quantum relaxation mechanism gradually predominates. The total rotational relaxation rate coefficients of D2(1,12) collisions with N2 and D2 at 295 K were determined to be 3.974 × 10−14 and 1.179 × 10−14 cm3 s−1, respectively. The temperature dependence of rotational relaxation rate of D2(1,12) was investigated within the temperature range of 295–453 K. With increasing temperature, the dominant relaxation process exhibited an accelerated behavior, while the minor relaxation process remained largely unaffected. The rotational temperature of the D2 molecule at various N2 molar ratios was determined through the utilization of Boltzmann plots. The rotational temperature undergoes a rapid decline within 2 μs, corresponding to the near-resonant rotation–vibration relaxation process of D2(1,12) collisions with N2. The system reaches a quasi-equilibrium state when the delay time is 3 μs. The findings of this study can serve as a valuable empirical basis for further validation of the kinetic theory and simulation.

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Collision Strengths of Astrophysical Interest for Multiply Charged Ions

Cited by 4 publications

References 59 publications

Rapid Access to Empirical Impact Ionization Cross Sections for Atoms and Ions across the Periodic Table

Rapid Access to Empirical Impact Ionization Cross Sections for Atoms and Ions across the Periodic Table

Generalized binary-encounter-Bethe model for electron impact ionization of atoms

Experimental study of rotational relaxation for D2(1,12) in collisions with N2

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