Measuring the extent of convective cores in low-mass stars using<i>Kepler</i>data: toward a calibration of core overshooting

Deheuvels, S.; Brandão, I. M.; Aguirre, V. Silva; Ballot, J.; Michel, E.; Cunha, M. S.; Lebreton, Y.; Appourchaux, T.

doi:10.1051/0004-6361/201527967

Cited by 127 publications

(145 citation statements)

References 74 publications

(116 reference statements)

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“…Our seismically derived overshoot values for the best models are f ov = 0.024 and α ov = 0.32. These are in excellent agreement with the previous studies (reviewed by Aerts 2013 and the references therein), in addition to those of Stancliffe et al (2015) from fitting the global observables of nine binary systems, between 1.3 and 6.2 M e , and the seismic modeling of Deheuvels et al (2016) for F stars at the onset of convective cores. Thus, a global picture of overshoot mixing for a broad range of stellar masses is gradually emerging.…”

Section: Summary Discussion and Conclusionsupporting

confidence: 91%

Sub-Inertial Gravity Modes in the B8v Star Kic 7760680 Reveal Moderate Core Overshooting and Low Vertical Diffusive Mixing

Moravveji

Townsend

Aerts

et al. 2016

ApJ

164

273

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Thus far, KIC 7760680 is the richest slowly pulsating B star, exhibiting 36 consecutive dipole (ℓ = 1) gravity (g-) modes. The monotonically decreasing period spacing of the series, in addition to the local dips in the pattern, confirm that KIC 7760680 is a moderate rotator with clear mode trapping in chemically inhomogeneous layers. We employ the traditional approximation of rotation to incorporate rotational effects on g-mode frequencies. Our detailed forward asteroseismic modeling of this g-mode series reveals that KIC 7760680 is a moderately rotating B star with mass ∼3.25 M e . By simultaneously matching the slope of the period spacing and the number of modes in the observed frequency range, we deduce that the equatorial rotation frequency of KIC 7760680 is 0.4805 day −1 , which is 26% of its Roche break up frequency. The relative deviation of the model frequencies and those observed is less than 1%. We succeed in tightly constraining the exponentially decaying convective core overshooting parameter to f ov ≈ 0.024 ± 0.001. This means that convective core overshooting can coexist with moderate rotation. Moreover, models with exponentially decaying overshoot from the core outperform those with the classical step-function overshoot. The best value for extra diffusive mixing in the radiatively stable envelope is confined to »  D log 0.75 0.25 ext (with D ext in cm 2 s −1 ), which is notably smaller than theoretical predictions.

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Section: Summary Discussion and Conclusionsupporting

confidence: 91%

Sub-Inertial Gravity Modes in the B8v Star Kic 7760680 Reveal Moderate Core Overshooting and Low Vertical Diffusive Mixing

Moravveji

Townsend

Aerts

et al. 2016

ApJ

164

273

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“…They cautioned that some of these can lead to significant biases in the inferred efficiency of convective overshooting from stellar models. Deheuvels et al (2016) dispensed with binaries altogether and used diagnostics from asteroseismology of single stars observed by the Kepler spacecraft to estimate the extent of the extra mixing for eight relatively low-mass stars (1.3-1.5 M ) in which this was possible. These authors reported hints that α ov may depend on mass even over this narrow range.…”

Section: Introductionmentioning

confidence: 99%

The dependence of convective core overshooting on stellar mass

Claret

Torres

2016

A&A

110

118

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Context. Convective core overshooting extends the main-sequence lifetime of a star. Evolutionary tracks computed with overshooting are very different from those that use the classical Schwarzschild criterion, which leads to rather different predictions for the stellar properties. Attempts over the last two decades to calibrate the degree of overshooting with stellar mass using detached double-lined eclipsing binaries have been largely inconclusive, mainly because of a lack of suitable observational data. Aims. We revisit the question of a possible mass dependence of overshooting with a more complete sample of binaries, and examine any additional relation there might be with evolutionary state or metal abundance Z. Methods. We used a carefully selected sample of 33 double-lined eclipsing binaries strategically positioned in the H-R diagram with accurate absolute dimensions and component masses ranging from 1.2 to 4.4 M . We compared their measured properties with stellar evolution calculations to infer semi-empirical values of the overshooting parameter α ov for each star. Our models use the common prescription for the overshoot distance d ov = α ov H p , where H p is the pressure scale height at the edge of the convective core as given by the Schwarzschild criterion, and α ov is a free parameter. Results. We find a relation between α ov and mass, which is defined much more clearly than in previous work, and indicates a significant rise up to about 2 M followed by little or no change beyond this mass. No appreciable dependence is seen with evolutionary state at a given mass, or with metallicity at a given mass although the stars in our sample span a range of a factor of ten in [Fe/H], from −1.01 to +0.01.

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“…This also applies to other stages of stellar evolution. With recent asteroseismological analyses constraining the convective cores during main-sequence evolution [92,93], a consistent picture might well emerge in the coming years.…”

Section: Resultsmentioning

confidence: 80%

Asteroseismic Constraints on the Models of Hot B Subdwarfs: Convective Helium-Burning Cores

2017

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Abstract.Asteroseismology of non-radial pulsations in Hot B Subdwarfs (sdB stars) offers a unique view into the interior of core-helium-burning stars. Ground-based and space-borne high precision light curves allow for the analysis of pressure and gravity mode pulsations to probe the structure of sdB stars deep into the convective core. As such asteroseismological analysis provides an excellent opportunity to test our understanding of stellar evolution. In light of the newest constraints from asteroseismology of sdB and red clump stars, standard approaches of convective mixing in 1D stellar evolution models are called into question. The problem lies in the current treatment of overshooting and the entrainment at the convective boundary. Unfortunately no consistent algorithm of convective mixing exists to solve the problem, introducing uncertainties to the estimates of stellar ages. Three dimensional simulations of stellar convection show the natural development of an overshooting region and a boundary layer. In search for a consistent prescription of convection in one dimensional stellar evolution models, guidance from three dimensional simulations and asteroseismological results is indispensable. Hot Subdwarf B starsSubdwarf B (sdB) stars are a class of hot (T eff = 20, 000−40, 000 K) and compact (log g = 5.0−6.2) stars with very thin hydrogen envelopes (M H < 0.01 M ) [1,2]. They form the so-called extreme horizontal branch (EHB) in the Hertzsprung-Russell diagram, where most of them quietly burn helium in their cores for ∼10 8 years. A violent process stripped them of most of their hydrogen envelope before they underwent the helium flash near the tip of the red giant branch (RGB). As a consequence they will not climb up the asymptotic giant branch (AGB) once their core helium is exhausted, but rather evolve directly to become white dwarfs.Although some sdB stars appear to be single and others occur in wide binaries, surveys have concluded that the majority are in close binaries with white dwarf or lowmass main sequence companions [3][4][5]. A small fraction of the latter exhibit eclipses, offering insight into the orbital parameters and masses of the systems. These HW Virginis stars, named after the discovery system, play a crucial role in determining the mass distribution of sdB stars. The median mass of sdB stars estimated from these binaries is 0.469 M [6].The formation scenarios for sdB stars have to explain their existence in both single and binary systems as well as introduce a process by which the hydrogen envelope of the progenitor stars can be lost. Common envelope ejection (CE) or stable Roche lobe overflow (RLOF) during binary evolution result in systems with close and wide e-mail: jtschindler@email.arizona.edu separations, respectively, [7]. Population synthesis models can well explain the occurrence of binary systems and the mass distribution of the primary and secondary components [8]. To explain the existence of single sdB stars, extreme mass loss on the RGB [9-11] as well as white dwarf mergers...

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Measuring the extent of convective cores in low-mass stars usingKeplerdata: toward a calibration of core overshooting

Cited by 127 publications

References 74 publications

Sub-Inertial Gravity Modes in the B8v Star Kic 7760680 Reveal Moderate Core Overshooting and Low Vertical Diffusive Mixing

Sub-Inertial Gravity Modes in the B8v Star Kic 7760680 Reveal Moderate Core Overshooting and Low Vertical Diffusive Mixing

The dependence of convective core overshooting on stellar mass

Asteroseismic Constraints on the Models of Hot B Subdwarfs: Convective Helium-Burning Cores

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