2013A&A...553A.112N -
Astronomy and Astrophysics, volume 553A, 112-112 (2013/5-1)
Understanding the dynamical structure of pulsating stars: the center-of-mass velocity and the Baade-Wesselink projection factor of the β Cephei star α Lupi.
NARDETTO N., MATHIAS P., FOKIN A., CHAPELLIER E., PIETRZYNSKI G., GIEREN W., GRACZYK D. and MOURARD D.
Abstract (from CDS):
High-resolution spectroscopy of pulsating stars is a powerful tool to study the dynamical structure of their atmosphere. Lines asymmetry is used to derive the center-of-mass velocity of the star, while a direct measurement of the atmospheric velocity gradient helps determine the projection factor used in the Baade-Wesselink method of distance determination. We aim at deriving the center-of-mass velocity and the projection factor of the β Cephei star α Lup. We present HARPS high spectral resolution observations of α Lup. We calculate the first-moment radial velocities and fit the spectral line profiles by a bi-Gaussian to derive line asymmetries. Correlations between the γ-velocity and the γ-asymmetry (defined as the average values of the radial velocity and line asymmetry curves respectively) are used to derive the center-of-mass velocity of the star. By combining our spectroscopic determination of the atmospheric velocity gradient with a hydrodynamical model of the photosphere of the star, we derive a semi-theoretical projection factor for α Lup. We find a center-of-mass velocity of Vγ=7.9 ±0.6 km/s and that the velocity gradient in the atmosphere of α Lup is null. We apply to α Lup the usual decomposition of the projection factor into three parts, p = p0 fgrad fog (originally developed for Cepheids), and derive a projection factor of p=1.43±0.01. By comparing our results with previous HARPS observations of classical Cepheids, we also point out a linear relation between the atmospheric velocity gradient and the amplitude of the radial velocity curve. Moreover, we observe a phase shift (Van Hoof effect), whereas α Lup has no velocity gradient. New HARPS data of a short-period β Cephei star, τ1 Lup, are also presented in this paper. By comparing Cepheids and β Cephei stars, these results bring insight into the dynamical structure of pulsating star atmospheres, which helps to better understand the k-term problem and the Baade-Wesselink p-factor for Cepheids.
Abstract Copyright:
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Journal keyword(s):
stars: oscillations - stars: atmospheres - line: profiles - stars: individual: tau01 Lup - stars: individual: α Lup - stars: distances
Simbad objects:
4
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