On the nature of sn stars

Saffe, C.; Levato, H.

doi:10.1051/0004-6361/201322091

Cited by 20 publications

(21 citation statements)

References 62 publications

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“…Abundances were determined iteratively by fitting different metallic lines using the program SYNTHE. For each element, Table 2 shows the average and the total error, minimum in χ 2 was reached, similarly to what was done by Saffe & Levato (2014). Abundance dispersions were estimated by quadratically adding the error of the average ξ and the abundance difference when varying T eff , log g, and v micro by their respective errors e ∆ .…”

Section: Stellar Parameters and Abundance Analysismentioning

confidence: 99%

KELT-17: a chemically peculiar Am star and a hot-Jupiter planet

Saffe

Miquelarena

Alacoria

et al. 2020

A&A

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Context. There is very little information to be found in the literature regarding the detection of planets orbiting chemically peculiar stars. Aims. Our aim is to determine the detailed chemical composition of the remarkable planet host star KELT-17. This object hosts a hot-Jupiter planet with 1.31 MJup detected by transits, and it is one of the more massive and rapidly rotating planet hosts seen to date. We set out to derive a complete chemical pattern for this star, in order to compare it with those of chemically peculiar stars. Methods. We carried out a detailed abundance determination in the planet host star KELT-17 via spectral synthesis. Stellar parameters were estimated iteratively by fitting Balmer line profiles and imposing the Fe ionization balance using the SYNTHE program together with plane-parallel ATLAS12 model atmospheres. Specific opacities for an arbitrary composition and microturbulence velocity vmicro were calculated through the opacity sampling (OS) method. The abundances were determined iteratively by fitting synthetic spectra to metallic lines of 16 different chemical species using SYNTHE. The complete chemical pattern of KELT-17 was compared to the recently published average pattern of Am stars. We estimated the stellar radius using two methods: a) comparing the synthetic spectral energy distribution with the available photometric data and the Gaia parallax, and b) using a Bayesian estimation of stellar parameters using stellar isochrones. Results. We found over-abundances of Ti, Cr, Mn, Fe, Ni, Zn, Sr, Y, Zr, and Ba, together with subsolar values of Ca and Sc. Notably, the chemical pattern agrees with those recently published for Am stars, making KELT-17 the first exoplanet host whose complete chemical pattern is unambiguously identified with this class. The stellar radius derived by two different methods agrees to each other and with those previously obtained in the literature.

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Section: Stellar Parameters and Abundance Analysismentioning

confidence: 99%

KELT-17: a chemically peculiar Am star and a hot-Jupiter planet

Saffe

Miquelarena

Alacoria

et al. 2020

A&A

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“…The updated version of the program FUNDPAR searches for a solution that simultaneously verifies the conditions 2 to 5. The use of the four mentioned conditions (2 to 5) were previously tested (for the "classical" non-differential case) using 61 main-sequence stars (Saffe 2011), 223 giant stars (Jofré et al 2015), and nine early-type stars (Saffe & Levato 2014), obtaining very similar parameters to the literature. Then, we applied these conditions for the differential line-by-line case, deriving for both stars stellar parameters in agreement with the literature and with lower errors, as we see later.…”

Section: Stellar Parameters and Chemical Abundance Analysismentioning

confidence: 99%

HD 80606: searching for the chemical signature of planet formation

Saffe

Flores

Buccino

2015

A&A

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Context. Binary systems with similar components are ideal laboratories that allow several physical processes to be tested, such as the possible chemical pattern imprinted by the planet formation process. Aims. We explore the probable chemical signature of planet formation in the remarkable binary system HD 80606−HD 80607. The star HD 80606 hosts a giant planet with ∼4 M Jup detected by both transit and radial velocity techniques, which is one of the most eccentric planets detected to date. We study condensation temperature T c trends of volatile and refractory element abundances to determine whether there is a depletion of refractories, which could be related to the terrestrial planet formation. Methods. We carried out a high-precision abundance determination in both components of the binary system via a line-by-line, strictly differential approach. First, we used the Sun as a reference and then we used HD 80606. The stellar parameters T eff , log g, (2009, A&A, 497, 563). The T c trends were also compared mutually between both stars of the binary system. Results. From the study of T c trends, we concluded that the stars HD 80606 and HD 80607 do not seem to be depleted in refractory elements, which is different for the case of the Sun. Then, following the interpretation of Meléndez et al. (2009), the terrestrial planet formation would have been less efficient in the components of this binary system than in the Sun. The lack of a trend in refractory elements with T c between both stars implies that the presence of a giant planet do not neccesarily imprint a chemical signature in their host stars, similar to the recent result of Liu et al. (2014, MNRAS, 442, L51). This is also in agreement with Meléndez et al. (2009), who suggest that the presence of close-in giant planets might prevent the formation of terrestrial planets. Finally, we speculate about a possible, ejected or non-detected, planet around the star HD 80607.

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“…However, that log g is not unprecedented among chemically peculiar stars in this temperature range, e.g. the HgMn star HD 63975 (log g = 3.27, Ndiaye et al 2018), the He-weak PGa star HD 23408 (log g = 3.3, Mon et al 1981;Monier & Khalack 2021), and the He-weak (probably not of the PGa type) HD 5737 (log g = 3.2, Leone & Manfre 1997;Saffe & Levato 2014). The low log g may influence atomic diffusion, and contribute to the atypical pattern of chemical abundances observed, although the impact of log g on atomic diffusion is not well studied.…”

Section: Chemical Peculiaritymentioning

confidence: 91%

A rare phosphorus-rich star in an eclipsing binary from TESS

Folsom,

Kama,

Eenmäe

et al. 2021

Preprint

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Context. Few exoplanets around hot stars with radiative envelopes have been discovered, although new observations from the TESS mission are improving this. Stars with radiative envelopes have little mixing at their surface, and thus their surface abundances provide a sensitive test case for a variety of processes including potentially star-planet interactions. Atomic diffusion is particularly important in these envelopes, producing chemically peculiar objects such as Am and HgMn stars.Aims. An exoplanet candidate around the B6 star HD 235349 was identified by TESS. Here we determine the nature of this transiting object and identify possible chemical peculiarities in the star. Methods. HD 235349 was observed using the long-slit spectrograph at Tartu Observatory, as well as photometrically by the TESS mission. The spectra were modeled to determine stellar parameters and chemical abundances. The photometric light curve was then analyzed in the context of the stellar parameters to determine properties of the transiting object. Results. We find the transiting object is a low-mass stellar companion, not a planet. However, the primary of this eclipsing binary is a rare type of chemically peculiar star. A strong overabundance of P is found with overabundances of Ne and Nd, and mild overabundances of Ti and Mn, while He is mildly underabundant. There is also clear evidence for vertical stratification of P in the atmosphere of the star. The lack of Hg and weak Mn overabundance suggests that this is not a typical HgMn star. It may be in the class of helium-weak phosphorus-gallium (He-weak PGa) stars, or an intermediate between these two classes. Conclusions. We show that HD 235349 is a rare type of chemically peculiar star (He-weak PGa) in an eclipsing binary system with a low-mass stellar companion. This appears to be the first He-weak PGa star discovered in an eclipsing binary.

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On the nature of sn stars

Cited by 20 publications

References 62 publications

KELT-17: a chemically peculiar Am star and a hot-Jupiter planet

KELT-17: a chemically peculiar Am star and a hot-Jupiter planet

HD 80606: searching for the chemical signature of planet formation

A rare phosphorus-rich star in an eclipsing binary from TESS

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