A plea for reexamining heavy element opacities in stars

Simon, Norman R.

doi:10.1086/183876

Cited by 193 publications

(88 citation statements)

References 6 publications

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“…Thus, the study of stellar pulsations provides indirect tests of opacities and has stimulated research. The "Z bump" is and important example, originally invoked to resolved mass discrepancies [26], soon after predicted by new opacity calculations [27,28], later corroborated by laboratory experiments [29] as well as pulsation studies [30], and now a standard feature in astrophysical opacities [31]. The Z bump is due to photon absorption by iron group elements.…”

Section: Stellar Envelope Opacitiesmentioning

confidence: 94%

Statistical line-by-line model for atomic spectra in intermediate coupling

Iglesias

2012

High Energy Density Physics

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The partially resolved transition array (PRTA) model is extended from JJ to intermediate coupling. The PRTA model conserves known array properties, yields improved higher moments, and systematically accounts for initial level populations. In addition, a random PRTA (R-PRTA) model is proposed to simulate detailed line accounting (DLA) calculations of complex spectra.Numerical examples show that the PRTA model with intermediate coupling reproduces the effects of the electrostatic interaction between spin-orbit split arrays on the spectrum. They also show that the R-PRTA model is in good agreement with DLA results and accounts for systematic line coincidences across transition arrays differing only in the subshell occupation of excited spectator electrons important in opacity calculations. Both PRTA and R-PRTA models are computationally much faster than DLA calculations. Hence, the models can accelerate spectrum calculations without introducing significant uncertainties whenever the DLA method is considered arduous or impractical.

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Section: Stellar Envelope Opacitiesmentioning

confidence: 94%

Statistical line-by-line model for atomic spectra in intermediate coupling

Iglesias

2012

High Energy Density Physics

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“…Figure 1 (left) shows that the spectrum can be interpreted with a rather high accuracy (except maybe as concerns the main feature around 1530 eV) using SCO-RCG at a single temperature and a single density. The spectrally-resolved transmission of aluminum was measured in the range of 70-280 eV at ρ = 0.01 g/cm 3 and T = 22 eV [28,29]. For this purpose, the iodine laser ASTERIX IV (200 J energy with pulse duration 0.4 ns at 400 nm) was focused into a spherical gold cavity with a diameter of 3 mm.…”

Section: Interpretation Of Experimentsmentioning

confidence: 99%

“…As can be seen in Figure 1 (right), the spectrum can be analyzed taking into account a temperature variation of 6 eV. [27] on HELEN laser facility in the United Kingdom and interpreted by SCO-RCG at T = 37 eV and ρ = 0.01 g/cm 3 . The areal mass is equal to 54 µg/cm 2 .…”

Section: Interpretation Of Experimentsmentioning

confidence: 99%

“…The areal mass is equal to 54 µg/cm 2 . Right: aluminum spectrum measured by Winhart et al [28,29] on ASTERIX IV laser facility in Germany and interpreted by SCO-RCG at ρ = 0.01 g/cm 3 and averaged over four temperatures (T = 18, 20, 22 and 24 eV) in order to simulate the gradients. The areal mass is equal to 30 µg/cm 2 .…”

Section: Interpretation Of Experimentsmentioning

confidence: 99%

“…The Cepheid stars (named after δ Cephei) are known to be used to estimate the stellar distances. They have been better understood after a revision by a factor two of the opacity for species of atomic number Z > 2 [3] confirmed by the first measurements of absorption coefficients [4]. The β Cephei-type stars (which should not be confused with Cepheid variables), also known as β Cepheids and named after β Cephei (or Alfirk) are now of primary interest due to the correlation between the frequencies of the excited modes and the mass of these stars for a given age.…”

Section: Introductionmentioning

confidence: 99%

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Detailed Opacity Calculations for Astrophysical Applications

Pain

Gilleron

Comet

2017

Atoms

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Nowadays, several opacity codes are able to provide data for stellar structure models, but the computed opacities may show significant differences. In this work, we present state-of-the-art precise spectral opacity calculations, illustrated by stellar applications. The essential role of laboratory experiments to check the quality of the computed data is underlined. We review some X-ray and XUV laser and Z-pinch photo-absorption measurements as well as X-ray emission spectroscopy experiments involving hot dense plasmas produced by ultra-high-intensity laser irradiation. The measured spectra are systematically compared with the fine-structure opacity code SCO-RCG. The focus is on iron, due to its crucial role in understanding asteroseismic observations of β Cephei-type and Slowly Pulsating B stars, as well as of the Sun. For instance, in β Cephei-type stars, the iron-group opacity peak excites acoustic modes through the "kappa-mechanism". Particular attention is paid to the higher-than-predicted iron opacity measured at the Sandia Z-machine at solar interior conditions. We discuss some theoretical aspects such as density effects, photo-ionization, autoionization or the "filling-the-gap" effect of highly excited states.

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2015

Pulsating Stars

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A plea for reexamining heavy element opacities in stars

Cited by 193 publications

References 6 publications

Statistical line-by-line model for atomic spectra in intermediate coupling

Statistical line-by-line model for atomic spectra in intermediate coupling

Detailed Opacity Calculations for Astrophysical Applications

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