TESS photometry and CAOS spectroscopy of six eclipsing binaries with Am components

Catanzaro, G.; Frasca, A.; Alonso-Santiago, J.; Colombo, C.

doi:10.1051/0004-6361/202449332

A&A

2024

DOI: 10.1051/0004-6361/202449332

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TESS photometry and CAOS spectroscopy of six eclipsing binaries with Am components

G. Catanzaro,

A. Frasca,

J. Alonso-Santiago

et al.

Abstract: In this paper, we present the results of a comprehensive study of six eclipsing binaries whose components are confirmed or suspected Am stars. By combining long-term, high-resolution Catania Astrophysical Observatory Spectropolarimeter (CAOS) spectroscopy and photometry, we have been able to accurately obtain the orbital parameters of each system as well as the atmospheric parameters of its components. We performed an in-depth chemical analysis and provided chemical abundances of C, O, Na, Mg, Si, Ca, Sc, Ti, … Show more

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Cited by 2 publications

References 59 publications

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Super-slowly rotating Ap (ssrAp) stars: Spectroscopic study

Mathys,

Holdsworth,

Giarrusso

et al. 2024

A&A

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The fact that the rotation periods of Ap stars span five to six orders of magnitude and that the longest ones reach several hundred years represents one of the main unsolved challenges of stellar physics. Our goal is to gain better understanding of the occurrence and properties of the longest period Ap stars. We obtained high resolution spectra of a sample of super-slowly rotating Ap (ssrAp) star candidates identified by a TESS photometric survey to confirm that they are indeed Ap stars, to check that their projected equatorial velocities are compatible with super-slow rotation, and to obtain a first estimate of their magnetic field strengths. For the confirmed Ap stars, we determined whenever possible their mean magnetic field modulus, their mean quadratic magnetic field, and an upper limit of their projected equatorial velocities. Eighteen of the 27 stars studied are typical Ap stars; most of the other nine appear to be misclassified. One of the Ap stars is not a slow rotator; it must be seen nearly pole-on. The properties of the remaining 17 are compatible with moderately to extremely long rotation periods. Eight new stars with resolved magnetically split lines in the visible range were discovered; their mean magnetic field modulus and their mean quadratic magnetic field were measured. The mean quadratic field could also be determined in five more stars. Five spectroscopic binaries containing an Ap star, which were not previously known, were identified. Among the misclassified stars, one double-lined spectroscopic binary with two similar, sharp-lined Am components was also discovered. The technique that we used to carry out a search for ssrAp star candidates using TESS data is validated. Its main limitation appears to arise from uncertainties in the spectral classification of Ap stars. The new magnetic field measurements obtained as part of this study lend further support to the tentative conclusions of our previous studies: the absence of periods $ in stars with $B_0 the lower rate of occurrence of super-slow rotation for field strengths $B_0 than in the range kG B_0 and the deficiency of slowly rotating Ap stars with (phase-averaged) field strengths between sim 2 and sim 3\,kG.

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Super-slowly rotating Ap (ssrAp) stars: Spectroscopic study

Mathys,

Holdsworth,

Giarrusso

et al. 2024

A&A

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The Radcliffe wave as traced by young open clusters

Alonso-Santiago,

Frasca,

Bragaglia

et al. 2024

A&A

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The Radcliffe wave has only recently been recognised as a approx 3\,kpc long coherent gas structure encompassing most of the star-forming regions in the solar vicinity. Since its discovery, it has been mainly studied from the perspective of dynamics, but a detailed chemical study is necessary to understand its nature and the composition of the natal clouds that gave rise to it. For this paper we used some of the connected young open clusters (age lesssim 100 Myr) as tracers of the molecular clouds. We performed high-resolution spectroscopy with GIARPS at the TNG of 53 stars that are bona fide members of seven clusters located at different positions along the Radcliffe wave. We provide radial velocities and atmospheric parameters for all of them. For a subsample consisting of 41 FGK stars, we also studied the chromospheric activity and the content of Li, from which we inferred the age of the parent clusters. These values agree with the evolutionary ages reported in the literature. For these FGK stars, we determined the chemical abundances for 25 species. Pleiades, ASCC\,16, and NGC\,7058 exhibit a solar metallicity while Melotte\,20, ASCC\,19, NGC\,2232, and Roslund\,6 show a slightly subsolar value (approx \,$-$0.1\,dex). On average, the clusters show a chemical composition compatible with that of the Sun, especially for alpha - and Fe-peak elements. Neutron-capture elements, on the other hand, present a slight overabundance of about 0.2\,dex, especially barium. Finally, considering also ASCC\,123, which was studied by our group in a previous research project, we inferred a correlation between the chemical composition and the age or position of the clusters along the wave, demonstrating their physical connection within an inhomogeneous mixing scenario.

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TESS photometry and CAOS spectroscopy of six eclipsing binaries with Am components

Cited by 2 publications

References 59 publications

Super-slowly rotating Ap (ssrAp) stars: Spectroscopic study

Super-slowly rotating Ap (ssrAp) stars: Spectroscopic study

The Radcliffe wave as traced by young open clusters

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