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

Wade, G. A.; Pigulski, A.; Begy, S.; Shultz, Matt; Handler, G.; Sikora, J.; Neilson, Hilding R.; Cugier, H.; Erba, C.; Moffat, A. F. J.; Pablo, B.; Weiß, W. W.; Zwintz, K.

doi:10.1093/mnras/staa025

Cited by 7 publications

(5 citation statements)

References 50 publications

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“…HD 46328 (ξ 1 CMa, B0.5 IV, Lesh 1968) is a well-studied high-amplitude β Cep star, with a single pulsation period of P = 0.209 d (McNamara 1955;Shobbrook 1973b;Heynderickx 1992;Heynderickx et al 1994;Saesen et al 2006;Shultz et al 2017Shultz et al , 2018Wade et al 2020b). Its one-sector TESS data set was most recently studied by Wade et al (2020b), who recover this period again and use it to constrain the period change over the last 100 yr. They also note the possible presence of g modes.…”

Section: Appendix B: Comments On Individual Objectsmentioning

confidence: 99%

Variability of OB stars from TESS southern Sectors 1–13 and high-resolution IACOB and OWN spectroscopy

Burssens

Simón‐Díaz

Bowman

et al. 2020

A&A

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Context. The lack of high-precision long-term continuous photometric data for large samples of stars has impeded the large-scale exploration of pulsational variability in the OB star regime. As a result, the candidates for in-depth asteroseismic modelling have remained limited to a few dozen dwarfs. The TESS nominal space mission has surveyed the southern sky, including parts of the galactic plane, yielding continuous data across at least 27 d for hundreds of OB stars. Aims. We aim to couple TESS data in the southern sky with ground-based spectroscopy to study the variability in two dimensions, mass and evolution. We focus mainly on the presence of coherent pulsation modes that may or may not be present in the predicted theoretical instability domains and unravel all frequency behaviour in the amplitude spectra of the TESS data. Methods. We compose a sample of 98 OB-type stars observed by TESS in Sectors 1–13 and with available multi-epoch, high-resolution spectroscopy gathered by the IACOB and OWN surveys. We present the short-cadence 2 min light curves of dozens of OB-type stars, which have one or more spectra in the IACOB or OWN database. Based on these light curves and their Lomb–Scargle periodograms, we performed variability classification and frequency analysis. We placed the stars in the spectroscopic Hertzsprung–Russell diagram to interpret the variability in an evolutionary context. Results. We deduce the diverse origins of the mmag-level variability found in all of the 98 OB stars in the TESS data. We find among the sample several new variable stars, including three hybrid pulsators, three eclipsing binaries, high frequency modes in a Be star, and potential heat-driven pulsations in two Oe stars. Conclusions. We identify stars for which future asteroseismic modelling is possible, provided mode identification is achieved. By comparing the position of the variables to theoretical instability strips, we discuss the current shortcomings in non-adiabatic pulsation theory and the distribution of pulsators in the upper Hertzsprung–Russell diagram.

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Section: Appendix B: Comments On Individual Objectsmentioning

confidence: 99%

Variability of OB stars from TESS southern Sectors 1–13 and high-resolution IACOB and OWN spectroscopy

Burssens

Simón‐Díaz

Bowman

et al. 2020

A&A

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“…Building on work by Pigulski [71], Jerzykiewicz [72] and Shultz et al [69], BRITE-Constellation photometry (BLb, BHr, BTr) of ξ 1 CMa was employed by Wade et al [73], as one of the most recent anchor points to monitor the evolution of its pulsation period. Combining over one century of photometric and radial velocity monitoring, they concluded that the period evolution of ξ 1 CMa consists of a secular period lengthening of roughly 0.3 s/century that can be satisfactorily understood as a consequence of expansion due to stellar evolution.…”

Section: Evolving Pulsation Of the Slowly Rotating Magnetic β Cephei Pulsator ξmentioning

confidence: 99%

Space Photometry with Brite-Constellation

et al. 2021

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BRITE-Constellation is devoted to high-precision optical photometric monitoring of bright stars, distributed all over the Milky Way, in red and/or blue passbands. Photometry from space avoids the turbulent and absorbing terrestrial atmosphere and allows for very long and continuous observing runs with high time resolution and thus provides the data necessary for understanding various processes inside stars (e.g., asteroseismology) and in their immediate environment. While the first astronomical observations from space focused on the spectral regions not accessible from the ground it soon became obvious around 1970 that avoiding the turbulent terrestrial atmosphere significantly improved the accuracy of photometry and satellites explicitly dedicated to high-quality photometry were launched. A perfect example is BRITE-Constellation, which is the result of a very successful cooperation between Austria, Canada and Poland. Research highlights for targets distributed nearly over the entire HRD are presented, but focus primarily on massive and hot stars.

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“…We calculated RV measurements (Table A1) from the individual subexposures of the spectropolarimetric sequences, following the multiline procedure described by . The RVs from the 2019 observations were published by Wade et al (2020). To calculate pulsation phase, we adopt the nonlinear ephemeris (P 0 = 0.2095763(1) d and Ṗ = 0.0096(5) s yr −1 ) from , consistent with the short-term period evolution described by Wade et al (2020).…”

Section: Espadons Spectropolarimetrymentioning

confidence: 99%

“…The RVs from the 2019 observations were published by Wade et al (2020). To calculate pulsation phase, we adopt the nonlinear ephemeris (P 0 = 0.2095763(1) d and Ṗ = 0.0096(5) s yr −1 ) from , consistent with the short-term period evolution described by Wade et al (2020).…”

Section: Espadons Spectropolarimetrymentioning

confidence: 99%

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Confirmation of ξ1 CMa’s ultra-slow rotation: magnetic polarity reversal and a dramatic change in magnetospheric UV emission lines

Erba

Shultz

Petit

et al. 2021

Monthly Notices of the Royal Astronomical Society

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The magnetic β Cep pulsator ξ1 CMa has the longest rotational period of any known magnetic B-type star. It is also the only magnetic B-type star with magnetospheric emission that is known to be modulated by both rotation and pulsation. We report here the first unambiguous detection of a negative longitudinal magnetic field in ξ1 CMa (〈Bz〉 = −87 ± 2 G in 2019 and 〈Bz〉 = −207 ± 3 G in 2020), as well as the results of ongoing monitoring of the star’s Hα variability. We examine evidence for deviation from a purely dipolar topology. We also report a new HST UV spectrum of ξ1 CMa obtained near magnetic null that is consistent with an equatorial view of the magnetosphere, as evidenced by its similarity to the UV spectrum of β Cep obtained near maximum emission. The new UV spectrum of ξ1 CMa provides additional evidence for the extremely long rotation period of this star via comparison to archival data.

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

Cited by 7 publications

References 50 publications

Variability of OB stars from TESS southern Sectors 1–13 and high-resolution IACOB and OWN spectroscopy

Variability of OB stars from TESS southern Sectors 1–13 and high-resolution IACOB and OWN spectroscopy

Space Photometry with Brite-Constellation

Confirmation of ξ1 CMa’s ultra-slow rotation: magnetic polarity reversal and a dramatic change in magnetospheric UV emission lines

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