Inelastic e+Mg collision data and its impact on modelling stellar and supernova spectra

Barklem, P. S.; Osorio, Yeisson; Fursa, Dmitry V.; Bray, Igor; Zatsarinny, Oleg; Bartschat, Klaus; Jerkstrand, A.

doi:10.1051/0004-6361/201730864

Cited by 25 publications

(54 citation statements)

References 40 publications

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“…The data presented there are given as matrices, following the ordering of indexes in Table 1 (i.e., the transition 1-2 corresponds to element (1,2)), one matrix for each temperature. The data from the CCC and BSR methods are generally in very good agreement, with the location (offset) and scale (scatter) of the ratio Υ i j (CCC)/Υ i j (BSR), assuming a log-normal distribution, 1.03 and 0.17, respectively (see Barklem et al (2017)). This indicates a mean offset of only 3% and scatter of 17%.…”

Section: E+k Rate Coefficientsmentioning

confidence: 66%

“…In non-LTE applications, the rate coefficient is required, which is calculated by folding the cross sections σ produced in the CCC and BSR calculations with the velocity distribution, assumed here to be the Maxwell distribution. The relevant equations are given in Barklem et al (2017), and the data presented here are similar in form. The effective collision strengths Υ i j from the CCC and BSR methods are calculated for transitions between the 15 lowest-lying states of K, which includes all states up to 6d at 3.93 eV; this is the complete set of low-lying states that are included in both calculations.…”

Section: E+k Rate Coefficientsmentioning

confidence: 99%

“…In this study, we present new data based on two modern close-coupling methods, namely the convergent close coupling method (CCC) and the B-spline R-matrix method (BSR). Osorio et al (2011) and Barklem et al (2017) demonstrated that the rate coefficients calculated via these two methods tend to agree better than a factor of two for lithium and magnesium.…”

Section: Introductionmentioning

confidence: 99%

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Non-LTE analysis of K I in late-type stars

Reggiani

Amarsi

Lind

et al. 2019

A&A

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Context. Older models of Galactic chemical evolution (GCE) predict [K/Fe] ratios as much as 1 dex lower than those inferred from stellar observations. Abundances of potassium are mainly based on analyses of the 7698 Å resonance line, and the discrepancy between GCE models and observations is in part caused by the assumption of local thermodynamic equilibrium (LTE) in spectroscopic analyses. Aims. We study the statistical equilibrium of K i, focusing on the non-LTE effects on the 7698 Å line. We aim to determine how non-LTE abundances of potassium can improve the analysis of its chemical evolution, and help to constrain the yields of GCE models. Methods. We construct a new model K i atom that employs the most up-to-date atomic data. In particular, we calculate and present inelastic e+K collisional excitation cross-sections from the convergent close-coupling (CCC) and the B-Spline R-matrix (BSR) methods, and H+K collisions from the two-electron model (LCAO). We constructed a fine, extended grid of non-LTE abundance corrections based on 1D MARCS models that span 4000 < T eff /K < 8000, 0.50 < log g < 5.00, −5.00 < [Fe/H] < +0.50, and applied the corrections to potassium abundances extracted from the literature. Results. In concordance with previous studies, we find severe non-LTE effects in the 7698 Å line. The line is stronger in non-LTE and the abundance corrections can reach ∼ −0.7 dex for solar-metallicity stars such as Procyon. We determine potassium abundances in six benchmark stars, and obtain consistent results from different optical lines. We explore the effects of atmospheric inhomogeneity by computing for the first time a full 3D non-LTE stellar spectrum of K i lines for a test star. We find that 3D modeling is necessary to predict a correct shape of the resonance 7698Å line, but the line strength is similar to that found in 1D non-LTE. Conclusions. Our non-LTE abundance corrections reduce the scatter and change the cosmic trends of literature potassium abundances. In the regime [Fe/H] −1.0 the non-LTE abundances show a good agreement with the GCE model with yields from rotating massive stars. The reduced scatter of the non-LTE corrected abundances of a sample of solar twins shows that line-by-line differential analysis techniques cannot fully compensate for systematic LTE modelling errors; the scatter introduced by such errors introduces a spurious dispersion to K evolution.

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Section: E+k Rate Coefficientsmentioning

confidence: 66%

Section: E+k Rate Coefficientsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Non-LTE analysis of K I in late-type stars

Reggiani

Amarsi

Lind

et al. 2019

A&A

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“…Barklem 2016a) not least in the area of ab initio calculations for inelastic collisions with electrons (e.g. Barklem et al 2017) and with atomic hydrogen (e.g. Barklem 2016b;Belyaev et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Carbon, oxygen, and iron abundances in disk and halo stars

Amarsi

Nissen

Skúladóttir

2019

A&A

126

106

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The abundances of carbon, oxygen, and iron in late-type stars are important parameters in exoplanetary and stellar physics, as well as key tracers of stellar populations and Galactic chemical evolution. However, standard spectroscopic abundance analyses can be prone to severe systematic errors, based on the assumption that the stellar atmosphere is one-dimensional (1D) and hydrostatic, and by ignoring departures from local thermodynamic equilibrium (LTE). In order to address this, we carried out three-dimensional (3D) non-LTE radiative transfer calculations for C I and O I, and 3D LTE radiative transfer calculations for Fe II, across the STAGGER-grid of 3D hydrodynamic model atmospheres. The absolute 3D non-LTE versus 1D LTE abundance corrections can be as severe as − 0.3 dex for C I lines in low-metallicity F dwarfs, and − 0.6 dex for O I lines in high-metallicity F dwarfs. The 3D LTE versus 1D LTE abundance corrections for Fe II lines are less severe, typically less than + 0.15 dex. We used the corrections in a re-analysis of carbon, oxygen, and iron in 187 F and G dwarfs in the Galactic disk and halo. Applying the differential 3D non-LTE corrections to 1D LTE abundances visibly reduces the scatter in the abundance plots. The thick disk and high-α halo population rise in carbon and oxygen with decreasing metallicity, and reach a maximum of [C/Fe] ≈ 0.2 and a plateau of [O/Fe] ≈ 0.6 at [Fe/H] ≈ −1.0. The low-α halo population is qualitatively similar, albeit offset towards lower metallicities and with larger scatter. Nevertheless, these populations overlap in the [C/O] versus [O/H] plane, decreasing to a plateau of [C/O] ≈ −0.6 below [O/H] ≈ −1.0. In the thin-disk, stars having confirmed planet detections tend to have higher values of C∕O at given [O/H]; this potential signature of planet formation is only apparent after applying the abundance corrections to the 1D LTE results. Our grids of line-by-line abundance corrections are publicly available and can be readily used to improve the accuracy of spectroscopic analyses of late-type stars.

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“…Here we are interested in the e-Mg scattering system. The CCC method has already been extensively applied to this problem to study the 3 1 P 1 optical excitation function [67], compare with measurement of ACPs at 20 eV [9,10], resolve convergence problems at low energies [10], address discrepancy with experiment for the total ionization cross section [68], and for astrophysical modeling [69]. Consequently, we only give a brief overview of the essential theoretical concepts.…”

Section: Convergent Close-coupling Theorymentioning

confidence: 99%