Period change and stellar evolution of<i>β</i>Cephei stars

Neilson, Hilding R.; Ignace, Richard

doi:10.1051/0004-6361/201526836

Cited by 15 publications

(17 citation statements)

References 61 publications

(104 reference statements)

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“…Since the period is growing, this is qualitatively consistent with the increasing radius of the star as expected due to stellar evolution on the main sequence (e.g. Neilson & Ignace 2015). As reported by those authors, the fractional rate of change of the pulsation period of a radially pulsating star due to evolving mass M and radius R on evolutionary timescales can be computed according to:…”

Section: Stellar Evolutionsupporting

confidence: 84%

“…Jerzykiewicz (1999), in his summary of period evolution of β Cep stars, cites a rate of period change of 0.37 ± 0.05 s/cen reported by Pigulski (1992a). Neilson & Ignace (2015) used those results to test the influence of rotation and convective core overshoot on models of massive star evolution, finding that the measured rate of period change of ξ 1 CMa was in good agreement with that predicted by models under the constraints applied by the physical parameters of Shultz (2016); Shultz et al (2017).…”

Section: Introductionmentioning

confidence: 86%

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Evolving pulsation of the slowly rotating magnetic β Cep star ξ1 CMa

Wade

Pigulski

Begy

et al. 2020

Monthly Notices of the Royal Astronomical Society

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Recent BRITE-Constellation space photometry of the slowly rotating, magnetic β Cep pulsator ξ 1 CMa permits a new analysis of its pulsation properties. Analysis of the twocolour BRITE data reveals the well-known single pulsation period of 0.209 d, along with its first and second harmonics. A similar analysis of SMEI and TESS observations yields compatible results, with the higher precision TESS observations also revealing several low-amplitude modes with frequencies below 5 d −1 ; some of these are likely g modes. The phase lag between photometric and radial velocity maxima -equal to 0.334 cycles -is significantly larger than the typical value of 1/4 observed in other large-amplitude β Cep stars. The phase lag, as well as the strong dependence of phase of maximum light on wavelength, can be reconciled with seismic models only if the dominant mode is the fundamental radial mode. We employ all published photometric and radial velocity measurements, spanning over a century, to evaluate the stability of the pulsation period. The O − C diagram exhibits a clear parabolic shape consistent with a mean rate of period change P = 0.34±0.02 s/cen. The residuals from the best-fit parabola exhibit scatter that is substantially larger than the uncertainties. In particular, dense sampling obtained during the past ∼20 years suggests more complex and rapid period variations. Those data cannot be coherently phased with the mean rate of period change, and instead require P ∼ 0.9 s/cen. We examine the potential contributions of binarity, stellar evolution, and stellar rotation and magnetism to understand the apparent period evolution.

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Section: Stellar Evolutionsupporting

confidence: 84%

Section: Introductionmentioning

confidence: 86%

Evolving pulsation of the slowly rotating magnetic β Cep star ξ1 CMa

Wade

Pigulski

Begy

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…This is because the southern CVZ of TESS includes the LMC galaxy, which allows pulsation excitation models to be tested for metal-rich and metal-poor stars (Bowman et al, 2019b). TESS also offers the opportunity to revisit "old friends" in terms of previously studied massive stars with high-precision photometry, which is particularly useful to probe the longterm stability in pulsation mode amplitudes and frequencies in relatively short-lived stars (e.g., Neilson and Ignace, 2015). The diverse variability of massive stars, which includes both coherent pulsation modes excited by the κ-mechanism and IGWs excited by core convection (Pedersen et al, 2019;Bowman et al, 2019b;Burssens et al, 2020), enables asteroseismology for a sample of massive stars larger by two orders of magnitude compared to any that came before.…”

Section: Conclusion and Future Prospectsmentioning

confidence: 99%

Asteroseismology of High-Mass Stars: New Insights of Stellar Interiors With Space Telescopes

Bowman

2020

Front. Astron. Space Sci.

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Massive stars are important metal factories in the Universe. They have short and energetic lives, and many of them inevitably explode as a supernova and become a neutron star or black hole. In turn, the formation, evolution and explosive deaths of massive stars impact the surrounding interstellar medium and shape the evolution of their host galaxies. Yet the chemical and dynamical evolution of a massive star, including the chemical yield of the ultimate supernova and the remnant mass of the compact object, strongly depend on the interior physics of the progenitor star. We currently lack empirically calibrated prescriptions for various physical processes at work within massive stars, but this is now being remedied by asteroseismology. The study of stellar structure and evolution using stellar oscillations-asteroseismology-has undergone a revolution in the last two decades thanks to high-precision time series photometry from space telescopes. In particular, the long-term light curves provided by the MOST, CoRoT, BRITE, Kepler/K2, and TESS missions provided invaluable data sets in terms of photometric precision, duration and frequency resolution to successfully apply asteroseismology to massive stars and probe their interior physics. The observation and subsequent modeling of stellar pulsations in massive stars has revealed key missing ingredients in stellar structure and evolution models of these stars. Thus, asteroseismology has opened a new window into calibrating stellar physics within a highly degenerate part of the Hertzsprung-Russell diagram. In this review, I provide a historical overview of the progress made using ground-based and early space missions, and discuss more recent advances and breakthroughs in our understanding of massive star interiors by means of asteroseismology with modern space telescopes.

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“…Since the pulsational frequency is proportional to the square root of the mean stellar density, pulsation is a sensitive indicator of the stellar evolution (see e.g. Neilson & Ignace 2015). For a 9 M star, the expected period variation isṖ/P ∼ 7 × 10 −8 yr −1 .…”

Section: Discussionmentioning

confidence: 99%

HD 96446: a long-period binary with a strongly magnetic He-rich primary with β Cephei pulsations

González

Briquet

Przybilla

et al. 2019

A&A

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Aims. HD 96446 is a magnetic B2p He-strong star that has been reported to be a β Cep pulsator. We present a detailed spectroscopic analysis of this object based on an intensive observational data set obtained in a multisite campaign with the spectrographs CORALIE, FEROS, and HARPS (La Silla); UVES (Paranal); HERCULES (Mt. John Observatory); and GIRAFFE (SAAO). Methods. Radial velocities were measured by cross-correlations and analysed to detect periodic variations. On the other hand, the mean spectrum was fit with spectral synthesis to derive atmospheric parameters and chemical abundances. Results. From the analysis of radial velocities, HD 96446 was found to be a spectroscopic binary with a period of 799 days. The stellar companion, which contributes only ∼5% of the total flux, is an A0-type star. A frequency analysis of the radial velocities allowed us to detect two pulsational modes with periods 2.23 h and 2.66 h. The main mode is most probably a low-inclination, dipole mode (l, m) = (1, 0), and the second pulsation mode corresponds to (l, m) = (2, 2) or to a pole-on (l, m) = (3, 2) configuration. In addition to radial velocities, the main pulsation mode is evidenced through small variations in the spectral morphology (temperature variations) and the light flux. The rotation period of 23.4 d, was detected through the variation in line intensities. Chemical abundances are unevenly distributed over the stellar surface, with helium concentrated at the negative magnetic pole and most metals strengthened at lower latitudes. The mean chemical abundance of helium is strongly abnormal, reaching a value of 0.60 (number fraction).

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Period change and stellar evolution ofβCephei stars

Cited by 15 publications

References 61 publications

Evolving pulsation of the slowly rotating magnetic β Cep star ξ1 CMa

Evolving pulsation of the slowly rotating magnetic β Cep star ξ1 CMa

Asteroseismology of High-Mass Stars: New Insights of Stellar Interiors With Space Telescopes

HD 96446: a long-period binary with a strongly magnetic He-rich primary with β Cephei pulsations

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