Phosphorus Abundances in the Hyades and Galactic Disk

Maas, Z. G.; Cescutti, G.; Pilachowski, Catherine A.

doi:10.3847/1538-3881/ab4a1a

Cited by 16 publications

(36 citation statements)

References 55 publications

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“…Fig. 1) which lead to a value of [P/Fe]~+0.6 in agreement with literature studies 13 . We also must emphasize that the N abundances are measured via the CN molecular lines and thus are strongly dependent on the O and C abundances because of molecular equilibrium.…”

Section: Chemical Abundance Analysissupporting

confidence: 91%

“…Phosphorus is extremely difficult to measure in stellar spectra because its lines are inherently weak and are only available in the near-IR or UV spectral ranges, which very few high-resolution spectrographs can actually cover. The astronomical restrictions are such that only few recent studies [1][2][3][4][5][6][7][8][9][10][11][12][13] have succeeded in measuring phosphorus in other stars than the Sun. Fortunately, the APOGEE spectrograph 14 (see Methods: Searching for P-rich stars) operates in the near-IR (Hband) and thus offers a unique opportunity to detect and measure phosphorus from stellar spectra.…”

Section: Introductionmentioning

confidence: 99%

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Phosphorus-rich stars with unusual abundances are challenging theoretical predictions

et al. 2020

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Almost all chemical elements have been made by nucleosynthetic reactions in various kind of stars and have been accumulated along our cosmic history. Among those elements, the origin of phosphorus is of extreme interest because it is known to be essential for life such as we know on Earth. However, current models of (Galactic) chemical evolution under-predict the phosphorus we observe in our Solar System. Here we report the discovery of 15 phosphorusrich stars with unusual overabundances of O, Mg, Si, Al, and Ce. Phosphorus-rich stars likely inherit their peculiar chemistry from another nearby stellar source but their intriguing chemical abundance pattern challenge the present stellar nucleosynthesis theoretical predictions. Specific effects such as rotation or advanced nucleosynthesis in convective-reactive regions in massive stars represent the most promising alternatives to explain the existence of phosphorus-rich stars. The phosphorus-rich stars progenitors may significantly contribute to the phosphorus present on Earth today.

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Section: Chemical Abundance Analysissupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Phosphorus-rich stars with unusual abundances are challenging theoretical predictions

et al. 2020

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“…These include heavier elements past the iron peak represented primarily by UV lines (e.g., Peterson 2011;Roederer et al 2016), and those whose IR lines are weak but detectable (e.g., Cunha et al 2017). Also included are lighter elements with sparse spectra such as fluorine (e.g., Jönsson et al 2014;Pilachowski & Pace 2015;Abia et al 2019) and phosphorus (e.g., Maas et al 2019). Heavy and light elements elucidate nucleosynthesis processes and environments at early epochs (Sneden et al 2008), and the delayed contribution of evolved asymptotic giant-branch stars (Pilachowski & Pace 2015).…”

Section: Status and Potential Impact Of Fe I Line Identificationsmentioning

confidence: 99%

New Fe i Level Energies and Line Identifications from Stellar Spectra. III. Initial Results from UV, Optical, and Infrared Spectra

Peterson¹,

Kurucz²

2022

ApJS

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The spectrum of neutral iron is critical to astrophysics, yet furnace laboratory experiments cannot reach high-lying Fe i levels. Instead, Peterson & Kurucz and Peterson et al. adopted ultraviolet (UV) and optical spectra of warm stars to identify and assign energies for 124 Fe i levels with 1900 detectable Fe i lines, and to derive astrophysical gf values for over 1000 of these. An energy value was assumed for each unknown Fe i level, and confirmed if the wavelengths predicted in updated Kurucz Fe i calculations matched the wavelengths of four or more unidentified lines in the observed spectra. Nearly all these identifications were for LS levels, those characterized by spin–orbit coupling, whose lines fall primarily at UV and optical wavelengths. This work contributes nearly 100 new Fe i level identifications. Thirty-nine LS levels are identified largely by incorporating published positions of unidentified laboratory Fe i lines with wavelengths <2000 Å. Adding infrared (IR) spectra provided 60 Fe i jK levels, where a single outer electron orbits a compact core. Their weak IR lines are searchable, because their mutual energies obey tight relationships. For each new Fe i level, this work again makes publicly available its identification, its energy, and a list of its potentially detectable lines with theoretical gf values, totalling >16,000 lines. For over 2000 of these, this work provides astrophysical gf values adjusted semiempirically to fit the stellar spectra. The potential impact of this work on modeling UV and IR stellar spectra is noted.

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“…Infrared abundances, i.e., from the 1053.24 and 1058.44 nm lines, were determined by Caffau et al (2011Caffau et al ( , 2016Caffau et al ( , 2019, with 0.04 dex, 0.04 dex, and 0.12 dex average uncertainties, respectively. Similarly, although using the 1058.1 and 1059.6 nm lines, Maas et al (2017) measured phosphorus in 22 stars, with an average 0.07 dex uncertainty and Maas et al (2019a) had an average uncertainty of 0.08 dex in 21 stars from the disk and Hyades cluster. Masseron et al (2020) used the APOGEE survey DR14 to measure neutral P lines at 1571.15 and 1648.29 nm for 30 stars likely originating from the Galactic thick disk or halo, with an average uncertainty of 0.15 dex.…”

Section: Stellar Elemental Abundance Datamentioning

confidence: 99%

The Influence of Stellar Phosphorus On Our Understanding of Exoplanets and Astrobiology

Hinkel¹,

Hartnett²,

Young³

2020

Preprint

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When searching for exoplanets and ultimately considering their habitability, it is necessary to consider the planet's composition, geophysical processes, and geochemical cycles in order to constrain the bioessential elements available to life. Determining the elemental ratios for exoplanetary ecosystems is not yet possible, but we generally assume that planets have compositions similar to those of their host stars. Therefore, using the Hypatia Catalog of high-resolution stellar abundances for nearby stars, we compare the C, N, Si, and P abundance ratios of main sequence stars with those in average marine plankton, Earth's crust, as well as bulk silicate Earth and Mars. We find that, in general, plankton, Earth, and Mars are N-poor and P-rich compared with nearby stars. However, the dearth of P abundance data, which exists for only ∼1% of all stars and 1% of exoplanet hosts, makes it difficult to deduce clear trends in the stellar data, let alone the role of P in the evolution of an exoplanet. Our Sun has relatively high P and Earth biology requires a small, but finite, amount of P. On rocky planets that form around host stars with substantially less P, the strong partitioning of P into the core could rule out the potential for surface P and, consequently, for life on that planet's surface. Therefore, we urge the stellar abundance community to make P observations a priority in future studies and telescope designs.

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Phosphorus Abundances in the Hyades and Galactic Disk

Cited by 16 publications

References 55 publications

Phosphorus-rich stars with unusual abundances are challenging theoretical predictions

Phosphorus-rich stars with unusual abundances are challenging theoretical predictions

New Fe i Level Energies and Line Identifications from Stellar Spectra. III. Initial Results from UV, Optical, and Infrared Spectra

The Influence of Stellar Phosphorus On Our Understanding of Exoplanets and Astrobiology

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