Bibcode
Beck, P. G.; Kallinger, T.; Pavlovski, K.; Palacios, A.; Tkachenko, A.; Mathis, S.; García, R. A.; Corsaro, E.; Johnston, C.; Mosser, B.; Ceillier, T.; do Nascimento, J.-D.; Raskin, G.
Bibliographical reference
Astronomy and Astrophysics, Volume 612, id.A22, 20 pp.
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4
2018
Journal
Citations
36
Refereed citations
30
Description
Context. Binaries in double-lined spectroscopic systems (SB2) provide a
homogeneous set of stars. Differences of parameters, such as age or
initial conditions, which otherwise would have strong impact on the
stellar evolution, can be neglected. The observed differences are
determined by the difference in stellar mass between the two components.
The mass ratio can be determined with much higher accuracy than the
actual stellar mass. Aim. In this work, we aim to study the eccentric
binary system KIC 9163796, whose two components are very close in mass
and both are low-luminosity red-giant stars. Methods: We analysed
four years of Kepler space photometry and we obtained high-resolution
spectroscopy with the Hermes instrument. The orbital elements and the
spectra of both components were determined using spectral disentangling
methods. The effective temperatures, and metallicities were extracted
from disentangled spectra of the two stars. Mass and radius of the
primary were determined through asteroseismology. The surface rotation
period of the primary is determined from the Kepler light curve. From
representative theoretical models of the star, we derived the internal
rotational gradient, while for a grid of models, the measured lithium
abundance is compared with theoretical predictions. Results: From
seismology the primary of KIC 9163796 is a star of 1.39 ± 0.06
M⊙, while the spectroscopic mass ratio between both
components can be determined with much higher precision by spectral
disentangling to be 1.015 ± 0.005. With such mass and a
difference in effective temperature of 600 K from spectroscopy, the
secondary and primary are, respectively, in the early and advanced stage
of the first dredge-up event on the red-giant branch. The period of the
primary's surface rotation resembles the orbital period within ten days.
The radial rotational gradient between the surface and core in KIC
9163796 is found to be 6.9-1.0+2.0. This is a low
value but not exceptional if compared to the sample of typical single
field stars. The seismic average of the envelope's rotation agrees with
the surface rotation rate. The lithium'abundance is in agreement with
quasi rigidly rotating models. Conclusions: The agreement between
the surface rotation with the seismic result indicates that the full
convective envelope is rotating quasi-rigidly. The models of the lithium
abundance are compatible with a rigid rotation in the radiative zone
during the main sequence. Because of the many constraints offered by
oscillating stars in binary systems, such objects are important test
beds of stellar evolution.
Based on observations made with the Kepler space telescope and the
Hermes spectrograph mounted on the 1.2 m Mercator Telescope at the
Spanish Observatorio del Roque de los Muchachos of the Instituto de
Astrofísica de Canarias.
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