2021
DOI: 10.1051/0004-6361/202140445
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The chemical make-up of the Sun: A 2020 vision

Abstract: Context. The chemical composition of the Sun is a fundamental yardstick in astronomy, relative to which essentially all cosmic objects are referenced. As such, having accurate knowledge of the solar elemental abundances is crucial for an extremely broad range of topics. Aims. We reassess the solar abundances of all 83 long-lived elements, using highly realistic solar modelling and state-of-the-art spectroscopic analysis techniques coupled with the best available atomic data and observations. Methods. The basis… Show more

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Cited by 402 publications
(369 citation statements)
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References 314 publications
(503 reference statements)
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“…In most cases, we find good agreement among the literature on stellar parameter values, which match up Note-log( F e ) = 7.46 (Asplund et al 2021) well with those presented here. However, in the case of WASP-17, we derived a T eff that is significantly lower than that of Anderson et al (2010), who present the discovery of WASP-17 b, by ∼400 K. Conversely, our measurement falls within ∼60 K of that derived by Gaia DR2 (Gaia Collaboration et al 2018).…”
Section: Literature Comparisonsupporting
confidence: 89%
See 1 more Smart Citation
“…In most cases, we find good agreement among the literature on stellar parameter values, which match up Note-log( F e ) = 7.46 (Asplund et al 2021) well with those presented here. However, in the case of WASP-17, we derived a T eff that is significantly lower than that of Anderson et al (2010), who present the discovery of WASP-17 b, by ∼400 K. Conversely, our measurement falls within ∼60 K of that derived by Gaia DR2 (Gaia Collaboration et al 2018).…”
Section: Literature Comparisonsupporting
confidence: 89%
“…Abundance data in log( X ) for target stars Note-Solar abundances fromAsplund et al (2021). Bracketed values are inferred from C and O (see Section 4.2.3) and not explicitly detected.…”
mentioning
confidence: 99%
“…The full field of view of camera Arm 1 is shown, with prominent lines identified using the lists of Moore, Minnaert, and Houtgast (1966) and Kurucz and Bell (1995). The 1.28-nm wide range covers several telluric O 2 lines that can be used for accurate wavelength referencing, a few photospheric Zeemansensitive Fe I lines including the widely used pair at 630.2 nm, temperature-sensitive Ti I lines, and the forbidden [O I] line that has been used for oxygen abundance studies (see, e.g., Asplund, Amarsi, and Grevesse, 2021). Figure 8 shows the four Stokes parameters from the same data in a wavelength band covering just the Fe I lines around 630.2 nm.…”
Section: Example Datamentioning
confidence: 99%
“…We measure an equivalent width for every absorption line in our line list that could be recognized, taking into consideration the quality of the spectrum in the vicinity of a line and the availability of alternative transitions of the same species. We assume Asplund et al (2021) solar abundances and local thermodynamic equilibrium (LTE) and use the 1D plane-parallel solar-composition ATLAS9 model atmospheres and the 2019 version of MOOG to infer elemental abundances based on each equivalent width measurement. We report our adopted atomic data, equivalent width measurements, and individual line-based abundance inferences in Table 2.…”
Section: Elemental Abundancesmentioning
confidence: 99%