Asteroseismology of Close Binary Stars: Tides and Mass Transfer

Guo, Zhao

doi:10.3389/fspas.2021.663026

Cited by 20 publications

(24 citation statements)

References 172 publications

(207 reference statements)

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“…See Section D in the appendix for a discussion of these techniques and their impact. Guo (2021) has given an extensive review of asteroseismology in close binary stars with particular emphasis on tides and the effects of mass transfer on pulsations and stellar structure. He examined both tidally excited and tidally perturbed, self-excited oscillations.…”

Section: Tides: Asteroseismology Of Close Binary Starsmentioning

confidence: 99%

“…In the highest eccentricity systems the periastron passage is within a few stellar radii, with stunning tidal distortions that then relax as the stars separate in the outer parts of the orbit. See Guo (2021) and Cheng et al ( 2020) for example light curves, FTs, and detailed discussion for some of these stars. Two results of the discovery of the heartbeat stars are that the previously untested theory of Kumar et al (1995) provides excellent fits to the wide variety of the orbital light variations that result primarily from different viewing angles and eccentricity, and that strong astrophysical inference about tidally excited oscillations can be made in the more than 20% of these systems that show pulsations.…”

Section: Tides: Asteroseismology Of Close Binary Starsmentioning

confidence: 99%

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Asteroseismology across the HR diagram

Kurtz¹

2022

Preprint

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Asteroseismology has grown from its beginnings three decades ago to a mature field teeming with discoveries and applications. This phenomenal growth has been enabled by space photometry with precision 10 − 100 times better than ground-based observations, with nearly continuous light curves for durations of weeks to years, and by large scale ground-based surveys spanning years designed to detect all timevariable phenomena. The new high precision data are full of surprises, deepening our understanding of the physics of stars.• This review explores asteroseismic developments from the last decade primarily as a result of light curves from the Kepler and TESS space missions for: massive upper main-sequence OBAF stars, pre-mainsequence stars, peculiar stars, classical pulsators, white dwarfs and subdwarfs, and tidally interacting close binaries. • The space missions have increased the numbers of pulsators in many classes by an order of magnitude. • Asteroseismology measures fundamental stellar parameters and stellar interior physics -mass, radius, age, metallicity, luminosity, distance, magnetic fields, interior rotation, angular momentum transfer, convective overshoot, core burning stage -supporting disparate fields such as galactic archeology, exoplanet host stars, supernovae progenitors, gamma ray and gravitational wave precursors, close binary star origins and evolution, and standard candles. • Stars are the luminous tracers of the universe. Asteroseismology significantly improves models of stellar structure and evolution on which all inference from stars depends.

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Section: Tides: Asteroseismology Of Close Binary Starsmentioning

confidence: 99%

Section: Tides: Asteroseismology Of Close Binary Starsmentioning

confidence: 99%

Asteroseismology across the HR diagram

Kurtz¹

2022

Preprint

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“…Significant advances have been made in tidal seismology after the discovery of the prototype heartbeat binary KOI-54 (HD 187091, KIC 8112039) by (Welsh et al 2011)(hereafter W11). Tidally Excited Oscillations (TEOs) have been observed in tens of heartbeat binary systems by the Kepler telescope (Thompson et al 2012;Kirk et al 2016;Cheng et al 2020;Guo 2021), and the TESS mission is unfolding more massive heartbeat binaries (Jayasinghe et al 2019;Kołaczek-Szymański et al 2021). Recently, nearly one thousand heartbeat stars in the OGLE survey have been reported by Wrona et al (2021).…”

Section: Introductionmentioning

confidence: 99%

A New Window to Tidal Asteroseismology: Non-linearly Excited Stellar Eigenmodes and the Period Spacing Pattern in KOI-54

Guo¹,

Ogilvie²,

Li³

et al. 2022

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We revisit the Tidally Excited Oscillations (TEOs) in the A-type, main-sequence, eccentric (𝑒 ≈ 0.83) binary KOI-54 (KIC 8112039), the prototype of heartbeat stars. Although the linear tidal response of the star is a series of orbital-harmonic frequencies which are not stellar eigenfrequencies, we show that the non-linearly excited non-orbital-harmonic TEOs are eigenmodes. By carefully choosing the modes having the same 𝑙 and 𝑚 which satisfy the mode-coupling selection rules, a period spacing (Δ𝑃) pattern of quadrupole gravity modes (Δ𝑃 ≈ 2520 sec) can be discerned in the Fourier spectrum and its echelle diagram. The inferred period spacing value agrees remarkably well with the theoretical 𝑙 = 2, 𝑚 = 0 g modes from a star with measured mass, radius and effective temperature. We also find that the two largest-amplitude TEOs at 𝑁 = 90, 91 harmonics are very close to resonance with 𝑙 = 2, 𝑚 = 0 eigenmodes, and likely come from different stars. They can essentially be regarded as eigenfrequencies to infer the stellar parameters.Previous works on tidal oscillations primarily focus on the modeling of TEO amplitudes and phases, and it was found that even a small change in the stellar models can significantly change the TEO amplitudes. Thus, the high sensitivity of TEO amplitude to the frequency detuning (tidal forcing frequency minus the closest stellar eigenfrequency) requires extremely dense grids of stellar models and prevents us from constraining the stellar physical parameters easily. This work, however, opens the window of real tidal asteroseismology by using the eigenfrequencies of the star inferred from the non-linear TEOs and possibly very-close-toresonance linear TEOs.Our seismic modeling of these identified eigen g-modes shows that the best-matching stellar models have (𝑀 ≈ 2.20, 2.35𝑀 ) and super-solar metallicity, in good agreement with previous measurements. We also discuss the effects of convective-core overshooting and metallicity on the observed g modes.

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“…A possibility of transferring energy from pulsations to orbit which may increase non-synchronicity of components or eccentricity of the system, so called inverse tides, was also found (Li et al 2020;Fuller 2021). A review of both the theory and observations of TEOs in massive binaries has been recently presented by Guo (2021).…”

Section: Introductionmentioning

confidence: 99%

Tidally excited oscillations in MACHO 80.7443.1718: Changing amplitudes and frequencies, high-frequency tidally excited mode, and a decrease in the orbital period

Kołaczek-Szymański,

Pigulski,

Wrona

et al. 2021

Preprint

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Context. Eccentric ellipsoidal variables (aka heartbeat stars) is a class of eccentric binaries in which proximity effects, tidal distortion due to time-dependent tidal potential in particular, lead to measurable photometric variability close to the periastron passage. Varying tidal potential may also give rise to tidally-excited oscillations (TEOs), which are forced eigenmodes with frequencies close to the integer multiples of the orbital frequency. TEOs may play an important role in the dynamical evolution of massive eccentric systems. Aims. Our study is aimed at detection of TEOs and characterisation of the long-term behaviour of their amplitudes and frequencies in the extreme-amplitude heartbeat star MACHO 80.7443.1718, consisting of a blue supergiant and a late O-type massive dwarf. Methods. We use two seasons of Transiting Exoplanet Survey Satellite (TESS) observations of the target to obtain new 30-min cadence photometry by means of the difference image analysis of TESS full-frame images. In order to extend the analysis to longer time scales, we supplement the TESS data with 30-years long ground-based photometry of the target. Both TESS and ground-based photometry is carefully analysed by means of Fourier techniques to detect TEOs, examine long-term stability of their amplitudes and frequencies, and characterise other types of variability in the system. Results. We confirm detection of the known n = 23, 25, and 41 TEOs and announce detection of two new TEOs, with n = 24 and 230, in the photometry of MACHO 80.7443.1718. Amplitudes of all TEOs were found to vary on a time scale of years or months. For n = 25 TEO amplitude and frequency changes are related, which may indicate that the main cause of the amplitude drop of this TEO in TESS observations is the change of its frequency and increase of detuning parameter. The light curve of the n = 230 TEO is strongly non-sinusoidal. Its high frequency may indicate that the oscillation is a strange mode. Stochastic variability observed in the target fits well the behaviour observed in massive stars and independently confirms that the primary is an evolved star. We also find that the orbital period of the system decreases at the rate of about 11 s (yr) −1 , which can be explained by a significant mass loss or mass transfer in the system with a possible contribution from tidal dissipation. Conclusions. Discovery of variable amplitudes and frequencies of TEOs prompt for similar studies in other eccentric elliptical variables with TEOs. Long-term photometric monitoring of these targets is also desirable. The results we obtained pose a challenge for theory. In particular, it needs to be explained why n = 230 TEO is excited. In a general context, studies of long-term behaviour of TEOs may help to explain the role of TEOs in the dynamical evolution of massive eccentric systems.

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Asteroseismology of Close Binary Stars: Tides and Mass Transfer

Cited by 20 publications

References 172 publications

Asteroseismology across the HR diagram

Asteroseismology across the HR diagram

A New Window to Tidal Asteroseismology: Non-linearly Excited Stellar Eigenmodes and the Period Spacing Pattern in KOI-54

Tidally excited oscillations in MACHO 80.7443.1718: Changing amplitudes and frequencies, high-frequency tidally excited mode, and a decrease in the orbital period

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