Your search keyword '"Stello D."' showing total 72 results

1. The GALAH survey: tracing the Galactic disc with open clusters.

Author

Spina, L, Ting, Y-S, De Silva, G M, Frankel, N, Sharma, S, Cantat-Gaudin, T, Joyce, M, Stello, D, Karakas, A I, Asplund, M B, Nordlander, T, Casagrande, L, D'Orazi, V, Casey, A R, Cottrell, P, Tepper-García, T, Baratella, M, Kos, J, Čotar, K, and Bland-Hawthorn, J

Subjects

OPEN clusters of stars, GALACTIC evolution, GALAXY clusters, FUNCTION spaces, STELLAR dynamics, ASTROMETRY, STAR clusters

Abstract

Open clusters are unique tracers of the history of our own Galaxy's disc. According to our membership analysis based on Gaia astrometry, out of the 226 potential clusters falling in the footprint of the GALactic Archaeology with HERMES (GALAH) survey or the Apache Point Observatory Galactic Evolution Experiment (APOGEE) survey, we find that 205 have secure members that were observed by at least one of the surveys. Furthermore, members of 134 clusters have high-quality spectroscopic data that we use to determine their chemical composition. We leverage this information to study the chemical distribution throughout the Galactic disc of 21 elements, from C to Eu. The radial metallicity gradient obtained from our analysis is −0.076 ± 0.009 dex kpc−1, which is in agreement with previous works based on smaller samples. Furthermore, the gradient in the [Fe/H]–guiding radius (r guid) plane is −0.073 ± 0.008 dex kpc−1. We show consistently that open clusters trace the distribution of chemical elements throughout the Galactic disc differently than field stars. In particular, at the given radius, open clusters show an age–metallicity relation that has less scatter than field stars. As such scatter is often interpreted as an effect of radial migration, we suggest that these differences are due to the physical selection effect imposed by our Galaxy: clusters that would have migrated significantly also had higher chances to get destroyed. Finally, our results reveal trends in the [X/Fe]– r guid–age space, which are important to understand production rates of different elements as a function of space and time. [ABSTRACT FROM AUTHOR]

Published

2021

2. The Aarhus red giants challenge II. Stellar oscillations in the red giant branch phase.

Author

Christensen-Dalsgaard, J., Aguirre, V. Silva, Cassisi, S., Bertolami, M. Miller, Serenelli, A., Stello, D., Weiss, A., Angelou, G., Jiang, C., Lebreton, Y., Spada, F., Bellinger, E. P., Deheuvels, S., Ouazzani, R. M., Pietrinferni, A., Mosumgaard, J. R., Townsend, R. H. D., Battich, T., Bossini, D., and Constantino, T.

Subjects

STELLAR oscillations, RED giants, STELLAR structure, FREQUENCIES of oscillating systems, STELLAR evolution, OSCILLATIONS

Abstract

Contact. The large quantity of high-quality asteroseismic data that have been obtained from space-based photometric missions and the accuracy of the resulting frequencies motivate a careful consideration of the accuracy of computed oscillation frequencies of stellar models, when applied as diagnostics of the model properties. Aims. Based on models of red-giant stars that have been independently calculated using different stellar evolution codes, we investigate the extent to which the differences in the model calculation affect the model oscillation frequencies and other asteroseismic diagnostics. Methods. For each of the models, which cover four different masses and different evolution stages on the red-giant branch, we computed full sets of low-degree oscillation frequencies using a single pulsation code and, from these frequencies, typical asteroseismic diagnostics. In addition, we carried out preliminary analyses to relate differences in the oscillation properties to the corresponding model differences. Results. In general, the differences in asteroseismic properties between the different models greatly exceed the observational precision of these properties. This is particularly true for the nonradial modes whose mixed acoustic and gravity-wave character makes them sensitive to the structure of the deep stellar interior and, hence, to details of their evolution. In some cases, identifying these differences led to improvements in the final models presented here and in Paper I; here we illustrate particular examples of this. Conclusions. Further improvements in stellar modelling are required in order fully to utilise the observational accuracy to probe intrinsic limitations in the modelling and improve our understanding of stellar internal physics. However, our analysis of the frequency differences and their relation to stellar internal properties provides a striking illustration of the potential, in particular, of the mixed modes of red-giant stars for the diagnostics of stellar interiors. [ABSTRACT FROM AUTHOR]

Published

2020

3. The Aarhus red giants challenge I. Stellar structures in the red giant branch phase.

Author

Aguirre, V. Silva, Christensen-Dalsgaard, J., Cassisi, S., Bertolami, M. Miller, Serenelli, A., Stello, D., Weiss, A., Angelou, G., Jiang, C., Lebreton, Y., Spada, F., Bellinger, E. P., Deheuvels, S., Ouazzani, R. M., Pietrinferni, A., Mosumgaard, J. R., Townsend, R. H. D., Battich, T., Bossini, D., and Constantino, T.

Subjects

STELLAR structure, RED giants, STELLAR oscillations, STELLAR evolution, STELLAR mass, PHYSICAL constants

Abstract

Context. With the advent of space-based asteroseismology, determining accurate properties of red-giant stars using their observed oscillations has become the focus of many investigations due to their implications in a variety of fields in astrophysics. Stellar models are fundamental in predicting quantities such as stellar age, and their reliability critically depends on the numerical implementation of the physics at play in this evolutionary phase. Aims. We introduce the Aarhus red giants challenge, a series of detailed comparisons between widely used stellar evolution and oscillation codes that aim to establish the minimum level of uncertainties in properties of red giants arising solely from numerical implementations. We present the first set of results focusing on stellar evolution tracks and structures in the red-giant-branch (RGB) phase. Methods. Using nine state-of-the-art stellar evolution codes, we defined a set of input physics and physical constants for our calculations and calibrated the convective efficiency to a specific point on the main sequence. We produced evolutionary tracks and stellar structure models at a fixed radius along the red-giant branch for masses of 1:0 M, 1:5 M, 2:0 M®, and 2:5 M®, and compared the predicted stellar properties. Results. Once models have been calibrated on the main sequence, we find a residual spread in the predicted effective temperatures across all codes of ~20K at solar radius and ~30-40K in the RGB regardless of the considered stellar mass. The predicted ages show variations of 2-5% (increasing with stellar mass), which we attribute to differences in the numerical implementation of energy generation. The luminosity of the RGB-bump shows a spread of about 10% for the considered codes, which translates into magnitude differences of ~0:1 mag in the optical V-band. We also compare the predicted [C/N] abundance ratio and find a spread of 0.1 dex or more for all considered masses. Conclusions. Our comparisons show that differences at the level of a few percent still remain in evolutionary calculations of red giants branch stars despite the use of the same input physics. These are mostly due to differences in the energy generation routines and interpolation across opacities, and they call for further investigation on these matters in the context of using properties of red giants as benchmarks for astrophysical studies. [ABSTRACT FROM AUTHOR]

Published

2020

4. Chromospheric emission of solar-type stars with asteroseismic ages.

Author

Booth, R S, Poppenhaeger, K, Watson, C A, Silva Aguirre, V, Stello, D, and Bruntt, H

Subjects

AGE of stars, STELLAR activity, STELLAR rotation, MAIN sequence (Astronomy), STELLAR chromospheres, MAGNETIC measurements, OLD age

Abstract

Stellar magnetic activity decays over the main-sequence life of cool stars due to the stellar spin-down driven by magnetic braking. The evolution of chromospheric emission is well studied for younger stars, but difficulties in determining the ages of older cool stars on the main sequence have complicated such studies for older stars in the past. Here, we report on chromospheric Ca  ii H and K line measurements for 26 main-sequence cool stars with asteroseismic ages older than a gigayear and spectral types F and G. We find that for the G stars and the cooler F-type stars that still have convective envelopes the magnetic activity continues to decrease at stellar ages above 1 Gyr. Our magnetic activity measurements do not show evidence for a stalling of the magnetic braking mechanism, which has been reported for stellar rotation versus age for G- and F-type stars. We also find that the measured |$R^{\prime }_{\mathrm{ HK}}$| indicator value for the cool F stars in our sample is lower than predicted by common age–activity relations that are mainly calibrated on data from young stellar clusters. We conclude that, within individual spectral type bins, chromospheric magnetic activity correlates well with stellar age even for old stars. [ABSTRACT FROM AUTHOR]

Published

2020

5. Analytical modelling of period spacings across the HR diagram.

Author

Cunha, M S, Avelino, P P, Christensen-Dalsgaard, J, Stello, D, Vrard, M, Jiang, C, and Mosser, B

Subjects

RED giants, HR diagrams, GRAVITY waves, SOUND waves, STELLAR oscillations, DATA modeling

Abstract

The characterization of stellar cores may be accomplished through the modelling of asteroseismic data from stars exhibiting either gravity-mode or mixed-mode pulsations, potentially shedding light on the physical processes responsible for the production, mixing, and segregation of chemical elements. In this work, we validate against model data an analytical expression for the period spacing that will facilitate the inference of the properties of stellar cores, including the detection and characterization of buoyancy glitches (strong chemical gradients). This asymptotically based analytical expression is tested both in models with and without buoyancy glitches. It does not assume that glitches are small and, consequently, predicts non-sinusoidal glitch-induced period-spacing variations, as often seen in model and real data. We show that the glitch position and width inferred from the fitting of the analytical expression to model data consisting of pure gravity modes are in close agreement (typically better than 7  |${{\ \rm per\ cent}}$| relative difference) with the properties measured directly from the stellar models. In the case of fitting mixed-mode model data, the same expression is shown to reproduce well the numerical results, when the glitch properties are known a priori. In addition, the fits performed to mixed-mode model data reveal a frequency dependence of the coupling coefficient, q , for a moderate-luminosity red-giant-branch model star. Finally, we find that fitting the analytical expression to the mixed-mode period spacings may provide a way to infer the frequencies of the pure acoustic dipole modes that would exist if no coupling took place between acoustic and gravity waves. [ABSTRACT FROM AUTHOR]

Published

2019

6. Surface correction of main-sequence solar-like oscillators with the Kepler LEGACY sample.

Author

Compton, D L, Bedding, T R, Ball, W H, Stello, D, Huber, D, White, T R, and Kjeldsen, H

Subjects

STELLAR oscillations, STELLAR mass, STELLAR evolution, ASTEROSEISMOLOGY, ASTROPHYSICS

Abstract

Poor modelling of the surface regions of solar-like stars causes a systematic discrepancy between the observed and model pulsation frequencies. We aim to characterize this frequency discrepancy for main-sequence solar-like oscillators for a wide range of initial masses and metallicities. We fit stellar models to the observed mode frequencies of the 67 stars, including the Sun, in the Kepler LEGACY sample, using three different empirical surface corrections. The three surface corrections we analyse are a frequency power-law, a cubic frequency term divided by the mode inertia and a linear combination of an inverse and cubic frequency term divided by the mode inertia. We construct a grid of stellar evolution models using the stellar evolution code mesa and calculate mode frequencies using gyre. We scale the frequencies of each stellar model by an empirical calculated homology coefficient, which greatly improves the robustness of our grid. We calculate stellar parameters and surface corrections for each star using the average of the best-fitting models from each evolutionary track, weighted by the likelihood of each model. The resulting model stellar parameters agree well with an independent reference, the BASTA pipeline. However, we find that the adopted physics of the stellar models has a greater impact on the fitted stellar parameters than the choice of correction method. We find that scaling the frequencies by the mode inertia improves the fit between the models and observations. The inclusion of the inverse frequency term produces substantially better model fits to lower surface gravity stars. [ABSTRACT FROM AUTHOR]

Published

2018

7. Confirming chemical clocks: asteroseismic age dissection of the Milky Way disc(s).

Author

Aguirre, V. Silva, Bojsen-Hansen, M., Slumstrup, D., Casagrande, L., Kawata, D., Ciucă, I., Handberg, R., Lund, M. N., Mosumgaard, J. R., Huber, D., Johnson, J. A., Pinsonneault, M. H., Serenelli, A. M., Stello, D., Tayar, J., Bird, J. C., Cassisi, S., Hon, M., Martig, M., and Nissen, P. E.

Subjects

DISKS (Astrophysics), GALACTIC evolution, STELLAR populations, STELLAR mergers, STELLAR structure

Abstract

Investigations of the origin and evolution of the Milky Way disc have long relied on chemical and kinematic identifications of its components to reconstruct our Galactic past. Difficulties in determining precise stellar ages have restricted most studies to small samples, normally confined to the solar neighbourhood. Here, we break this impasse with the help of asteroseismic inference and perform a chronology of the evolution of the disc throughout the age of the Galaxy. We chemically dissect the Milky Way disc population using a sample of red giant stars spanning out to 2 kpc in the solar annulus observed by the Kepler satellite, with the added dimension of asteroseismic ages. Our results reveal a clear difference in age between the low- and high-α populations, which also show distinct velocity dispersions in the V and W components. We find no tight correlation between age and metallicity nor [α/Fe] for the high-α disc stars. Our results indicate that this component formed over a period of more than 2 Gyr with a wide range of [M/H] and [α/Fe] independent of time. Our findings show that the kinematic properties of young α-rich stars are consistent with the rest of the high-α population and different from the low-α stars of similar age, rendering support to their origin being old stars that went through a mass transfer or stellar merger event, making them appear younger, instead of migration of truly young stars formed close to the Galactic bar. [ABSTRACT FROM AUTHOR]

Published

2018

8. Metallicity effect on stellar granulation detected from oscillating red giants in open clusters.

Author

Corsaro, E., Mathur, S., García, R. A., Gaulme, P., Pinsonneault, M., Stassun, K., Stello, D., Tayar, J., Trampedach, R., Jiang, C., Nitschelm, C., and Salabert, D.

Subjects

STELLAR granulation, RED giants, OPEN clusters of stars, ASTRONOMICAL photometry

Abstract

Context. The effect of metallicity on the granulation activity in stars, and hence on the convective motions in general, is still poorly understood. Available spectroscopic parameters from the updated APOGEE-Kepler catalog, coupled with high-precision photometric observations from NASA's Kepler mission spanning more than four years of observation, make oscillating red giant stars in open clusters crucial testbeds. Aims. We aim to determine the role of metallicity on the stellar granulation activity by discriminating its effect from that of different stellar properties such as surface gravity, mass, and temperature. We analyze 60 known red giant stars belonging to the open clusters NGC6791, NGC6819, and NGC6811, spanning a metallicity range from [Fe/H] ≃ -0:09 to 0:32. The parameters describing the granulation activity of these stars and their frequency of maximum oscillation power, max, are studied while taking into account different masses, metallicities, and stellar evolutionary stages.We derive new scaling relations for the granulation activity, re-calibrate existing ones, and identify the best scaling relations from the available set of observations. Methods. We adopted the Bayesian code Diamonds for the analysis of the background signal in the Fourier spectra of the stars. We performed a Bayesian parameter estimation and model comparison to test the different model hypotheses proposed in this work and in the literature. Results. Metallicity causes a statistically significant change in the amplitude of the granulation activity, with a dependency stronger than that induced by both stellar mass and surface gravity.We also find that the metallicity has a significant impact on the corresponding time scales of the phenomenon. The effect of metallicity on the time scale is stronger than that of mass. Conclusions. A higher metallicity increases the amplitude of granulation and meso-granulation signals and slows down their characteristic time scales toward longer periods. The trend in amplitude is in qualitative agreement with predictions from existing 3D hydrodynamical simulations of stellar atmospheres from main sequence to red giant stars. We confirm that the granulation activity is not sensitive to changes in the stellar core and that it only depends on the atmospheric parameters of stars. [ABSTRACT FROM AUTHOR]

Published

2017

9. Surface rotation of Kepler red giant stars.

Author

Ceillier, T., Tayar, J., Mathur, S., Salabert, D., García, R. A., Stello, D., Pinsonneault, M. H., van Saders, J., Beck, P. G., and Bloemen, S.

Subjects

RED giants, STARSPOTS, STELLAR evolution, STELLAR mergers

Abstract

Kepler allows the measurement of starspot variability in a large sample of field red giants for the first time. With a new method that combines autocorrelation and wavelet decomposition, we measure 361 rotation periods from the full set of 17 377 oscillating red giants in our sample. This represents 2.08% of the stars, consistent with the fraction of spectroscopically detected rapidly rotating giants in the field. The remaining stars do not show enough variability to allow us to measure a reliable surface rotation period. Because the stars with detected rotation periods have measured oscillations, we can infer their global properties, e.g. mass and radius, and quantitatively evaluate the predictions of standard stellar evolution models as a function of mass. Consistent with results for cluster giants when we consider only the 4881 intermediate-mass stars, M > 2.0 M⊙ from our full red giant sample, we do not find the enhanced rates of rapid rotation expected from angular momentum conservation. We therefore suggest that either enhanced angular momentum loss or radial differential rotation must be occurring in these stars. Finally, when we examine the 575 low-mass (M< 1.1 M⊙) red clump stars in our sample, which were expected to exhibit slow (non-detectable) rotation, 15% of them actually have detectable rotation. This suggests a high rate of interactions and stellar mergers on the red giant branch. [ABSTRACT FROM AUTHOR]

Published

2017

10. Kepler observations of the asteroseismic binary HD 176465.

Author

White, T. R., Benomar, O., Aguirre, V. Silva, Ball, W. H., Bedding, T. R., Chaplin, W. J., Christensen-Dalsgaard, J., Garcia, R. A., Gizon, L., Stello, D., Aigrain, S., Antia, H. M., Appourchaux, T., Bazot, M., Campante, T. L., Creevey, O. L., Davies, G. R., Elsworth, Y. P., Gaulme, P., and Handberg, R.

Subjects

BINARY stars, STELLAR evolution, STELLAR oscillations, STAR formation

Abstract

Binary star systems are important for understanding stellar structure and evolution, and are especially useful when oscillations can be detected and analysed with asteroseismology. However, only four systems are known in which solar-like oscillations are detected in both components. Here, we analyse the fifth such system, HD 176465, which was observed by Kepler. We carefully analysed the system's power spectrum to measure individual mode frequencies, adapting our methods where necessary to accommodate the fact that both stars oscillate in a similar frequency range. We also modelled the two stars independently by fitting stellar models to the frequencies and complementary parameters. We are able to cleanly separate the oscillation modes in both systems. The stellar models produce compatible ages and initial compositions for the stars, as is expected from their common and contemporaneous origin. Combining the individual ages, the system is about 3:0 ± 0:5 Gyr old. The two components of HD 176465 are young physicallysimilar oscillating solar analogues, the first such system to be found, and provide important constraints for stellar evolution and asteroseismology. [ABSTRACT FROM AUTHOR]

Published

2017

11. Oscillations in g-mode period spacings in red giants as a way to determine their state of evolution.

Author

Cunha, M. S., Stello, D., Avelino, P. P., and Christensen-Dalsgaard, J.

Subjects

STELLAR oscillations, RED giants, STELLAR evolution, INTERIOR of stars

Abstract

In this work we consider the sensitivity of gravity-mode period spacings to sharp changes in the inner structure of red giant stars, more specifically in the buoyancy frequency inside the g-mode propagation cavity. Based on a comparison between the solutions to the linear pulsation equations in the Cowling approximation for pure g-modes with results obtained with a full oscillation code we identify and correctly interpret the signature of the above-mentioned sharp variations in the period spacings. Two examples, of red giant models in different evolutionary phases, are discussed. Detection of these signatures in CoRoT, Kepler or future PLATO red-giant stars would pin down their evolutionary state in an unprecedented way. [ABSTRACT FROM AUTHOR]

Published

2015

12. Binary star detectability in Kepler data from phase modulation of different types of oscillations.

Author

Compton, D. L., Bedding, T. R., Murphy, S. J., and Stello, D.

Subjects

BINARY stars, ASTRONOMICAL photometry, ECLIPSES, SIGNAL-to-noise ratio, PHASE modulation, OSCILLATIONS

Abstract

Detecting binary stars in photometric time series is traditionally done by measuring eclipses. This requires the orbital plane to be aligned with the observer. A new method without that requirement uses stellar oscillations to measure delays in the light arrival time and has been successfully applied to δScuti stars. However, application to other types of stars has not been explored. To investigate this, we simulated light curves with a range of input parameters. We find a correlation between the signal to noise of the pulsation modes and the time delay required to detect binary motion. The detectability of the binarity in the simulations and in real, Kepler data show strong agreement, hence, we describe the factors that have prevented this method from discovering binary companions to stars belonging to various classes of pulsating stars. [ABSTRACT FROM AUTHOR]

Published

2016

13. Towards 21st century stellar models: Star clusters, supercomputing and asteroseismology.

Author

Campbell, S. W., Constantino, T. N., D'Orazi, V., Meakin, C., Stello, D., Christensen-Dalsgaard, J., Kuehn, C., De Silva, G. M., Arnett, W. D., Lattanzio, J. C., and MacLean, B. T.

Subjects

STAR clusters, ASTRONOMICAL photometry, STELLAR evolution, HYDRODYNAMICS, INTERIOR of stars

Abstract

Stellar models provide a vital basis for many aspects of astronomy and astro-physics. Recent advances in observational astronomy - through asteroseismology, precision photometry, high-resolution spectroscopy, and large-scale surveys - are placing stellar models under greater quantitative scrutiny than ever. The model limitations are being exposed and the next generation of stellar models is needed as soon as possible. The current uncertainties in the models propagate to the later phases of stellar evolution, hindering our understanding of stellar populations and chemical evolution. Here we give a brief overview of the evolution, importance, and substantial uncertainties of core helium burning stars in particular and then briefly discuss a range of methods, both theoretical and observational, that we are using to advance the modelling. [ABSTRACT FROM AUTHOR]

Published

2016

14. Modelling the Milky Way with Galaxia and making use of asteroseismology.

Author

Sharma, S., Stello, D., and Bland-Hawthorn, J.

Subjects

STELLAR populations, GALAXIES, VELOCITY distribution (Statistical mechanics), DISTRIBUTION (Probability theory), PHOTOMETRY

Abstract

Stellar population synthesis based models of the Milky Way play a crucial role in understanding and interpreting observational data from large surveys of the Milky Way. We describe the basic theoretical framework for modelling the Milky Way and discuss algorithms for generating a synthetic sample of stars out of such models. Next, we discuss how asteroseismology can be used to test and possibly refine theoretical models of the Milky Way. As an application we test the ability of Galaxia to reproduce the properties of stars observed by the NASA Kepler mission. We present some preliminary results. We find that Galaxia can reproduce the photometric properties of the sample. Additionally, it can also reproduce the distribution of average asteroseismic parameters and radius. In future, comparing the mass distributions will allow us to test the Galactic models more rigorously. [ABSTRACT FROM AUTHOR]

Published

2016

15. Oscillation frequencies for 35 Kepler solar-type planet-hosting stars using Bayesian techniques and machine learning.

Author

Davies, G. R., Aguirre, V. Silva, Bedding, T. R., Handberg, R., Lund, M. N., Chaplin, W. J., Huber, D., White, T. R., Benomar, O., Hekker, S., Basu, S., Campante, T. L., Christensen-Dalsgaard, J., Elsworth, Y., Karoff, C., Kjeldsen, H., Lundkvist, M. S., Metcalfe, T. S., and Stello, D.

Subjects

OSCILLATIONS, BAYESIAN analysis, SEISMOLOGY, MACHINE learning

Abstract

Kepler has revolutionized our understanding of both exoplanets and their host stars. Asteroseismology is a valuable tool in the characterization of stars and Kepler is an excellent observing facility to perform asteroseismology. Here we select a sample of 35 Kepler solar-type stars which host transiting exoplanets (or planet candidates) with detected solar-like oscillations. Using available Kepler short cadence data up to Quarter 16 we create power spectra optimized for asteroseismology of solar-type stars. We identify modes of oscillation and estimate mode frequencies by 'peak bagging' using a Bayesian Markov Chain Monte Carlo framework. In addition, we expand the methodology of quality assurance using a Bayesian unsupervised machine learning approach. We report the measured frequencies of the modes of oscillation for all 35 stars and frequency ratios commonly used in detailed asteroseismic modelling. Due to the high correlations associated with frequency ratios we report the covariance matrix of all frequencies measured and frequency ratios calculated. These frequencies, frequency ratios, and covariance matrices can be used to obtain tight constraint on the fundamental parameters of these planet-hosting stars. [ABSTRACT FROM AUTHOR]

Published

2016

16. Measuring the vertical age structure of the Galactic disc using asteroseismology and SAGA.

Author

Casagrande, L., Aguirre, V. Silva, Schlesinger, K. J., Stello, D., Huber, D., Serenelli, A. M., Schönrich, R., Cassisi, S., Pietrinferni, A., Hodgkin, S., Milone, A. P., Feltzing, S., and Asplund, M.

Subjects

MILKY Way, ASTRONOMICAL photometry, GALAXIES, OSCILLATIONS, ASTRONOMY

Abstract

The existence of a vertical age gradient in the Milky Way disc has been indirectly known for long. Here, we measure it directly for the first time with seismic ages, using red giants observed by Kepler. We use Strömgren photometry to gauge the selection function of asteroseismic targets, and derive colour and magnitude limits where giants with measured oscillations are representative of the underlying population in the field. Limits in the 2MASS system are also derived. We lay out a method to assess and correct for target selection effects independent of Galaxy models. We find that low-mass, i.e. old red giants dominate at increasing Galactic heights, whereas closer to the Galactic plane they exhibit a wide range of ages and metallicities. Parametrizing this as a vertical gradient returns approximately 4 Gyr kpc-1 for the disc we probe, although with a large dispersion of ages at all heights. The ages of stars show a smooth distribution over the last 1≃0 Gyr, consistent with a mostly quiescent evolution for the Milky Way disc since a redshift of about 2. We also find a flat age--metallicity relation for disc stars. Finally, we show how to use secondary clump stars to estimate the present-day intrinsic metallicity spread, and suggest using their number count as a new proxy for tracing the ageing of the disc. This work highlights the power of asteroseismology for Galactic studies; however, we also emphasize the need for better constraints on stellar mass-loss, which is a major source of systematic age uncertainties in red giant stars. [ABSTRACT FROM AUTHOR]

Published

2016

17. Ages and fundamental properties of Kepler exoplanet host stars from asteroseismology.

Author

Aguirre, V. Silva, Davies, G. R., Basu, S., Christensen-Dalsgaard, J., Creevey, O., Metcalfe, T. S., Bedding, T. R., Casagrande, L., Handberg, R., Lund, M. N., Nissen, P. E., Chaplin, W. J., Huber, D., Serenelli, A. M., Stello, D., Van Eylen, V., Campante, T. L., Elsworth, Y., Gilliland, R. L., and Hekker, S.

Subjects

ASTRONOMICAL observations, SIGNAL-to-noise ratio, STELLAR oscillations, STELLAR evolution, STELLAR mass

Abstract

We present a study of 33 Kepler planet-candidate host stars for which asteroseismic observations have sufficiently high signal-to-noise ratio to allow extraction of individual pulsation frequencies. We implement a new Bayesian scheme that is flexible in its input to process individual oscillation frequencies, combinations of them, and average asteroseismic parameters, and derive robust fundamental properties for these targets. Applying this scheme to grids of evolutionary models yields stellar properties with median statistical uncertainties of 1.2?per?cent (radius), 1.7?per?cent (density), 3.3?per?cent (mass), 4.4?per?cent (distance), and 14?per?cent (age), making this the exoplanet host-star sample with the most precise and uniformly determined fundamental parameters to date. We assess the systematics from changes in the solar abundances and mixing-length parameter, showing that they are smaller than the statistical errors. We also determine the stellar properties with three other fitting algorithms and explore the systematics arising from using different evolution and pulsation codes, resulting in 1?per?cent in density and radius, and 2?per?cent and 7?per?cent in mass and age, respectively. We confirm previous findings of the initial helium abundance being a source of systematics comparable to our statistical uncertainties, and discuss future prospects for constraining this parameter by combining asteroseismology and data from space missions. Finally, we compare our derived properties with those obtained using the global average asteroseismic observables along with effective temperature and metallicity, finding excellent level of agreement. Owing to selection effects, our results show that the majority of the high signal-to-noise ratio asteroseismic Kepler host stars are older than the Sun. [ABSTRACT FROM AUTHOR]

Published

2015

18. Asteroseismic inference on rotation, gyrochronology and planetary system dynamics of 16 Cygni.

Author

Davies, G. R., Chaplin, W. J., Farr, W. M., García, R. A., Lund, M. N., Mathis, S., Metcalfe, T. S., Appourchaux, T., Basu, S., Benomar, O., Campante, T. L., Ceillier, T., Elsworth, Y., Handberg, R., Salabert, D., and Stello, D.

Subjects

STELLAR rotation, SEISMOLOGY, PLANETARY surfaces, P Cygni stars, STELLAR oscillations

Abstract

The solar analogues 16 Cyg A and B are excellent asteroseismic targets in the Kepler field of view and together with a red dwarf and a Jovian planet form an interesting system. For these more evolved Sun-like stars we cannot detect surface rotation with the current Kepler data but instead use the technique of asteroseimology to determine rotational properties of both 16 Cyg A and B. We find the rotation periods to be 23.8-1.8+1.5 and 23.2-3.2+11.5d, and the angles of inclination to be 56-5+6° and 36-7+17°, for A and B, respectively. Together with these results we use the published mass and age to suggest that, under the assumption of a solar-like rotation profile, 16 Cyg A could be used when calibrating gyrochronology relations. In addition, we discuss the known 16 Cyg B star-planet eccentricity and measured low obliquity which is consistent with Kozai cycling and tidal theory. [ABSTRACT FROM AUTHOR]

Published

2015

19. Internal rotation of red giants by asteroseismology.

Author

Di Mauro, M. P., Cardini, D., Ventura, R., Stello, D., Beck, P. G., Davies, G., Elsworth, Y., García, R. A., Hekker, S., Mosser, B., Christensen-Dalsgaard, J., Bloemen, S., Catanzaro, G., De Smedt, K., and Tkachenko, A.

Subjects

RED giants, STELLAR rotation, OSCILLATIONS, GALAXIES

Abstract

We present an asteroseismic approach to study the dynamics of the stellar interior in red giant stars by asteroseismic inversion of the splittings induced by the stellar rotation on the oscillation frequencies. We show preliminary results obtained for the red giant KIC4448777 observed by the space mission Kepler. [ABSTRACT FROM AUTHOR]

Published

2013

20. Welcome back, Polaris the Cepheid.

Author

Bruntt, H., Penny, A. J., Stello, D., Evans, N. R., and Eaton, J. A.

Subjects

POLESTAR, CEPHEIDS, SUPERGIANT stars, PULSATING stars, BINARY stars

Abstract

For about 100 years the amplitude of the 4 d pulsation in Polaris has decreased. We present new results showing a significant increase in the amplitude based on 4.5 years of continuous monitoring from the ground and with two satellite missions. [ABSTRACT FROM AUTHOR]

Published

2009

21. Impact on asteroseismic analyses of regular gaps in Kepler data.

Author

García, R. A., Mathur, S., Pires, S., Régulo, C., Bellamy, B., Pallé, P. L., Ballot, J., Barceló Forteza, S., Beck, P. G., Bedding, T. R., Ceillier, T., Roca Cortés, T., Salabert, D., and Stello, D.

Subjects

STELLAR photometry, RED giants, LIGHT curves, POWER spectra

Abstract

Context. The NASA Kepler mission has observed more than 190 000 stars in the constellations of Cygnus and Lyra. Around 4 years of almost continuous ultra high-precision photometry have been obtained reaching a duty cycle higher than 90% for many of these stars. However, almost regular gaps due to nominal operations are present in the light curves on different time scales. Aims. In this paper we want to highlight the impact of those regular gaps in asteroseismic analyses, and we try to find a method that minimizes their effect on the frequency domain. Methods. To do so, we isolate the two main time scales of quasi regular gaps in the data.We then interpolate the gaps and compare the power density spectra of four different stars: two red giants at different stages of their evolution, a young F-type star, and a classical pulsator in the instability strip. Results. The spectra obtained after filling the gaps in the selected solar-like stars show a net reduction in the overall background level, as well as a change in the background parameters. The inferred convective properties could change as much as ~200% in the selected example, introducing a bias in the p-mode frequency of maximum power. When asteroseismic scaling relations are used, this bias can lead to a variation in the surface gravity of 0.05 dex. Finally, the oscillation spectrum in the classical pulsator is cleaner than the original one. [ABSTRACT FROM AUTHOR]

Published

2014

22. Study of KIC 8561221 observed by Kepler: an early red giant showing depressed dipolar modes?

Author

García, R. A., Hernández, F. Pérez, Benomar, O., Aguirre, V. Silva, Ballot, J., Davies, G. R., Doğan, G., Stello, D., Christensen-Dalsgaard, J., Houdek, G., Lignières, F., Mathur, S., Takata, M., Ceillier, T., Chaplin, W. J., Mathis, S., Mosser, B., Ouazzani, R. M., Pinsonneault, M. H., and Reese, D. R.

Subjects

RED giants, STELLAR structure, STELLAR magnetic fields, AMPLITUDE estimation

Abstract

Context. The continuous high-precision photometric observations provided by the CoRoT and Kepler space missions have allowed us to understand the structure and dynamics of red giants better using asteroseismic techniques. A small fraction of these stars show dipole modes with unexpectedly low amplitudes. The reduction in amplitude is more pronounced for stars with a higher frequency of maximum power, Vmax. Aims. In this work we want to characterise KIC 8561221 in order to confirm that it is currently the least evolved star among this peculiar subset and to discuss several hypotheses that could help explain the reduction of the dipole mode amplitudes. Methods. We used Kepler short- and long-cadence data combined with spectroscopic observations to infer the stellar structure and dynamics of KIC 8561221. We then discussed different scenarios that could contribute to reducing the dipole amplitudes, such as a fast-rotating interior or the effect of a magnetic field on the properties of the modes. We also performed a detailed study of the inertia and damping of the modes. Results. We have been able to characterise 36 oscillations modes, in particular, a few dipole modes above Vmax that exhibit nearly normal amplitudes. The frequencies of all the measured modes were used to determine the overall properties and the internal structure of the star.We have inferred a surface rotation period of ~91 days and uncovered a variation in the surface magnetic activity during the last 4 years. The analysis of the convective background did not reveal any difference compared to "normal" red giants. As expected, the internal regions of the star probed by the ⨏ = 2 and 3 modes spin 4 to 8 times faster than the surface. Conclusions. With our grid of standard models we are able to properly fit the observed frequencies. Our model calculation of mode inertia and damping give no explanation for the depressed dipole modes. A fast-rotating core is also ruled out as a possible explanation. Finally, we do not have any observational evidence of a strong deep magnetic field inside the star. [ABSTRACT FROM AUTHOR]

Published

2014

23. ASTEROSEISMIC FUNDAMENTAL PROPERTIES OF SOLAR-TYPE STARS OBSERVED BY THE NASA KEPLER MISSION.

Author

Chaplin, W. J., Basu, S., Huber, D., Serenelli, A., Casagrande, L., Aguirre, V. Silva, Ball, W. H., Creevey, O. L., Gizon, L., Handberg, R., Karoff, C., Lutz, R., Marques, J. P., Miglio, A., Stello, D., Suran, M. D., Pricopi, D., Metcalfe, T. S., Monteiro, M. J. P. F. G., and Molenda-Żakowicz, J.

Published

2014

24. Asteroseismic surface gravity for evolved stars.

Author

Hekker, S., Elsworth, Y., Mosser, B., Kallinger, T., Basu, S., Chaplin, W. J., and Stello, D.

Subjects

STELLAR evolution, SPECTRUM analysis, OSCILLATIONS, SPECTROSCOPIC imaging, KEPLER'S conjecture, RED giants

Abstract

Context. Asteroseismic surface gravity values can be important for determining spectroscopic stellar parameters. The independent log(g) value from asteroseismology can be used as a fixed value in the spectroscopic analysis to reduce uncertainties because log(g) and effective temperature cannot be determined independently from spectra. Since 2012, a combined analysis of seismically and spectroscopically derived stellar properties has been ongoing for a large survey with SDSS/APOGEE and Kepler. Therefore, knowledge of any potential biases and uncertainties in asteroseismic log(g) values is now becoming important. Aims. The seismic parameter needed to derive log(g) is the frequency of maximum oscillation power (vmax). Here, we investigate the influence on the derived log(g) values of ?max derived with different methods. The large frequency separation between modes of the same degree and consecutive radial orders (Δv) is often used as an additional constraint for determining log(g). Additionally, we checked the influence of small corrections applied to Δv on the derived values of log(g). Methods. We use methods extensively described in the literature to determine ?max and Δv together with seismic scaling relations and grid-based modelling to derive log(g). Results. We find that different approaches to derive oscillation parameters give results for log(g) with small, but different, biases for red-clump and red-giant-branch stars. These biases are well within the quoted uncertainties of ∼0.01 dex (cgs). Corrections suggested in the literature to the Δv scaling relation have no significant effect on log(g); however, somewhat unexpectedly, method specific solar reference values induce biases close to the uncertainties, which is not the case when canonical solar reference values are used. [ABSTRACT FROM AUTHOR]

Published

2013

25. PROPERTIES OF OSCILLATION MODES IN SUBGIANT STARS OBSERVED BY KEPLER.

Author

BENOMAR, O., BEDDING, T. R., MOSSER, B., STELLO, D., BELKACEM, K., GARCIA, R. A., WHITE, T. R., KUEHN, C. A., DEHEUVELS, S., and CHRISTENSEN-DALSGAARD, J.

Subjects

SUBGIANT stars, GIANT stars, PHYSICS, OSCILLATIONS

Abstract

Mixed modes seen in evolved stars carry information on their deeper layers that can place stringent constraints on their physics and on their global properties (mass, age, etc.). In this study, we present a method to identify and measure all oscillatory mode characteristics (frequency, height, width). Analyzing four subgiant stars, we present the first measure of the effect of the degree of mixture on the l = 1 mixed mode characteristics. We also show that some stars have measurable l = 2 mixed modes and discuss the interest of their measure to constrain the deeper layers of stars. [ABSTRACT FROM AUTHOR]

Published

2013

26. A Bayesian approach to scaling relations for amplitudes of solar-like oscillations in Kepler stars.

Author

Corsaro, E., Fröhlich, H.-E., Bonanno, A., Huber, D., Bedding, T. R., Benomar, O., De Ridder, J., and Stello, D.

Subjects

AMPLITUDE estimation, SOLAR oscillations, KEPLER problem, GIANT stars, POWER spectra, BAYESIAN analysis

Abstract

We investigate different amplitude scaling relations adopted for the asteroseismology of stars that show solar-like oscillations. Amplitudes are among the most challenging asteroseismic quantities to handle because of the large uncertainties that arise in measuring the background level in the star's power spectrum. We present results computed by means of a Bayesian inference on a sample of 1640 stars observed with Kepler, spanning from main sequence to red giant stars, for 12 models used for amplitude predictions and exploiting recently well-calibrated effective temperatures from Sloan Digital Sky Survey photometry. We test the candidate amplitude scaling relations by means of a Bayesian model comparison. We find the model having a separate dependence upon the mass of the stars to be largely the most favoured one. The differences among models and the differences seen in their free parameters from early to late phases of stellar evolution are also highlighted. [ABSTRACT FROM AUTHOR]

Published

2013

27. ASTEROSEISMIC DETERMINATION OF OBLIQUITIES OF THE EXOPLANET SYSTEMS KEPLER-50 AND KEPLER-65.

Author

CHAPLIN, W. J., SANCHIS-OJEDA, R., CAMPANTE, T. L., HANDBERG, R., STELLO, D., WINN, J. N., BASU, S., CHRISTENSEN-DALSGAARD, J., DAVIES, G. R., METCALFE, T. S., BUCHHAVE, L. A., FISCHER, D. A., BEDDING, T. R., COCHRAN, W. D., ELSWORTH, Y., GILLILAN, R. L., HEKKER, S., HUBER, D., ISAACSON, H., and KAROFF, C.

Subjects

OBLIQUITY-induced precession, EXTRASOLAR planets, STELLAR spectra, EARLY stars, COPLANAR transmission lines, SOLAR oscillations

Abstract

Results on the obliquity of exoplanet host stars—the angle between the stellar spin axis and the planetary orbital axis—provide important diagnostic information for theories describing planetary formation. Here we present the first application of asteroseismology to the problem of stellar obliquity determination in systems with transiting planets and Sun-like host stars.We consider two systems observed by theNASA Kepler mission which have multiple transiting small (super-Earth sized) planets: the previously reported Kepler-50 and a new system, Kepler-65, whose planets we validate in this paper. Both stars show rich spectra of solar-like oscillations. From the asteroseismic analysis we find that each host has its rotation axis nearly perpendicular to the line of sight with the sines of the angles constrained at the 1σ level to lie above 0.97 and 0.91, respectively. We use statistical arguments to show that coplanar orbits are favored in both systems, and that the orientations of the planetary orbits and the stellar rotation axis are correlated. [ABSTRACT FROM AUTHOR]

Published

2013

28. Spin down of the core rotation in red giants.

Author

Mosser, B., Goupil, M. J., Belkacem, K., Marques, J. P., Beck, P. G., Bloemen, S., J. De Ridder, Barban, C., Deheuvels, S., Elsworth, Y., Hekker, S., Kallinger, T., Ouazzani, R. M., Pinsonneault, M., Samadi, R., Stello, D., García, R. A., Klaus, T. C., Li, J., and Mathur, S.

Subjects

RED giants, ASTRONOMICAL photometry, STELLAR rotation, STELLAR activity, LINEAR statistical models

Abstract

Context. The space mission Kepler provides us with long and uninterrupted photometric time series of red giants. We are now able to probe the rotational behaviour in their deep interiors using the observations of mixed modes. Aims. We aim to measure the rotational splittings in red giants and to derive scaling relations for rotation related to seismic and fundamental stellar parameters. Methods. We have developed a dedicated method for automated measurements of the rotational splittings in a large number of red giants. Ensemble asteroseismology, namely the examination of a large number of red giants at different stages of their evolution, allows us to derive global information on stellar evolution. Results. We have measured rotational splittings in a sample of about 300 red giants. We have also shown that these splittings are dominated by the core rotation. Under the assumption that a linear analysis can provide the rotational splitting, we observe a small increase of the core rotation of stars ascending the red giant branch. Alternatively, an important slow down is observed for red-clump stars compared to the red giant branch. We also show that, at fixed stellar radius, the specific angular momentum increases with increasing stellar mass. Conclusions. Ensemble asteroseismology indicates what has been indirectly suspected for a while: our interpretation of the observed rotational splittings leads to the conclusion that the mean core rotation significantly slows down during the red giant phase. The slow-down occurs in the last stages of the red giant branch. This spinning down explains, for instance, the long rotation periods measured in white dwarfs. [ABSTRACT FROM AUTHOR]

Published

2012

29. Spin down of the core rotation in red giants.

Author

Mosser, B., Goupil, M. J., Belkacem, K., Marques, J. P., Beck, P. G., Bloemen, S., De Ridder, J., Barban, C., Deheuvels, S., Elsworth, Y., Hekker, S., Kallinger, T., Ouazzani, R. M., Pinsonneault, M., Samadi, R., Stello, D., García, R. A., Klaus, T. C., J. Li, and Mathur, S.

Subjects

RED giants, KEPLER'S conjecture, ANGULAR momentum (Nuclear physics), PHOTOMETRY, STARS

Abstract

Context. The space mission Kepler provides us with long and uninterrupted photometric time series of red giants. We are now able to probe the rotational behaviour in their deep interiors using the observations of mixed modes. Aims. We aim to measure the rotational splittings in red giants and to derive scaling relations for rotation related to seismic and fundamental stellar parameters. Methods. We have developed a dedicated method for automated measurements of the rotational splittings in a large number of red giants. Ensemble asteroseismology, namely the examination of a large number of red giants at different stages of their evolution, allows us to derive global information on stellar evolution. Results. We have measured rotational splittings in a sample of about 300 red giants. We have also shown that these splittings are dominated by the core rotation. Under the assumption that a linear analysis can provide the rotational splitting, we observe a small increase of the core rotation of stars ascending the red giant branch. Alternatively, an important slow down is observed for red-clump stars compared to the red giant branch. We also show that, at fixed stellar radius, the specific angular momentum increases with increasing stellar mass. Conclusions. Ensemble asteroseismology indicates what has been indirectly suspected for a while: our interpretation of the observed rotational splittings leads to the conclusion that the mean core rotation significantly slows down during the red giant phase. The slowdown occurs in the last stages of the red giant branch. This spinning down explains, for instance, the long rotation periods measured in white dwarfs. [ABSTRACT FROM AUTHOR]

Published

2012

30. A pulsation zoo in the hot subdwarf B star KIC 10139564 observed by Kepler A pulsation zoo in the hot subdwarf B star KIC 10139564 observed by Kepler.

Author

Baran, A. S., Reed, M. D., Stello, D., Østensen, R. H., Telting, J. H., Pakštienė, E., O'Toole, S. J., Silvotti, R., Degroote, P., Bloemen, S., Hu, H., Van Grootel, V., Clarke, B. D., Van Cleve, J., Thompson, S. E., and Kawaler, S. D.

Subjects

STELLAR oscillations, DWARF stars, B stars, ASTRONOMICAL observations, KEPLER'S laws, SEISMOLOGY, ASTRONOMICAL photometry, STELLAR rotation

Abstract

ABSTRACT We present our analyses of 15 months of Kepler data on KIC 10139564. We detected 57 periodicities with a variety of properties not previously observed all together in one pulsating subdwarf B (sdB) star. Ten of the periodicities were found in the low-frequency region, and we associate them with nonradial g modes. The other periodicities were found in the high-frequency region, which are likely p modes. We discovered that most of the periodicities are components of multiplets with a common spacing. Assuming that multiplets are caused by rotation, we derive a rotation period of 25.6 ± 1.8 d. The multiplets also allow us to identify the pulsations to an unprecedented extent for this class of pulsator. We also detect l ≥ 2 multiplets, which are sensitive to the pulsation inclination and can constrain limb darkening via geometric cancellation factors. While most periodicities are stable, we detected several regions that show complex patterns. Detailed analyses showed that these regions are complicated by several factors. Two are combination frequencies that originate in the super-Nyquist region and were found to be reflected below the Nyquist frequency. The Fourier peaks are clear in the super-Nyquist region, but the orbital motion of Kepler smears the Nyquist frequency in the barycentric reference frame and this effect is passed on to the sub-Nyquist reflections. Others are likely multiplets but unstable in amplitudes and/or frequencies. The density of periodicities also makes KIC 10139564 challenging to explain using published models. This menagerie of properties should provide tight constraints on structural models, making this sdB star the most promising for applying asteroseismology. To support our photometric analysis, we have obtained spectroscopic radial-velocity measurements of KIC 10139564 using low-resolution spectra in the Balmer-line region. We did not find any radial-velocity variation. We used our high signal-to-noise average spectrum to improve the atmospheric parameters of the sdB star, deriving Teff = 31 859 K and log g = 5.673 dex. [ABSTRACT FROM AUTHOR]

Published

2012

31. Solar-like oscillations in red giants observed with Kepler: influence of increased timespan on global oscillation parameters.

Author

Hekker, S., Elsworth, Y., Mosser, B., Kallinger, T., Chaplin, W. J., De Ridder, J., García, R. A., Stello, D., Clarke, B. D., Hall, J. R., and Ibrahim, K. A.

Subjects

OSCILLATIONS, KEPLER'S laws, RED giants, FLUX (Energy), DEPENDENCE (Statistics)

Abstract

Context. The length of the asteroseismic timeseries obtained from the Kepler satellite analysed here span 19 months. Kepler provides the longest continuous timeseries currently available, which calls for a study of the influence of the increased timespan on the accuracy and precision of the obtained results. Aims. We aim to investigate how the increased timespan influences the detectability of the oscillation modes, and the absolute values and uncertainties of the global oscillation parameters, i.e., frequency of maximum oscillation power, ?max, and large frequency separation between modes of the same degree and consecutive orders, ?Δ? ? . Methods. We use published methods to derive ?max and ?Δ? ? for timeseries ranging from 50 to 600 days and compare these results as a function of method, timespan and ?Δ? ? . Results. We find that in general a minimum of the order of 400 day long timeseries are necessary to obtain reliable results for the global oscillation parameters in more than 95% of the stars, but this does depend on ?Δ? ? . In a statistical sense the quoted uncertainties seem to provide a reasonable indication of the precision of the obtained results in short (50-day) runs, they do however seem to be overestimated for results of longer runs. Furthermore, the different definitions of the global parameters used in the different methods have non-negligible effects on the obtained values. Additionally, we show that there is a correlation between ?max and the flux variance. Conclusions. We conclude that longer timeseries improve the likelihood to detect oscillations with automated codes (from ∼60% in 50 day runs to >95% in 400 day runs with a slight method dependence) and the precision of the obtained global oscillation parameters. The trends suggest that the improvement will continue for even longer timeseries than the 600 days considered here, with a reduction in the median absolute deviation of more than a factor of 10 for an increase in timespan from 50 to 2000 days (the currently foreseen length of the mission). This work shows that global parameters determined with high precision - thus from long datasets - using different definitions can be used to identify the evolutionary state of the stars. [ABSTRACT FROM AUTHOR]

Published

2012

32. Age and helium content of the open cluster NGC 6791 from multiple eclipsing binary members II. Age dependencies and new insights.

Author

Brogaard, K., VandenBerg, D. A., Bruntt, H., Grundahl, F., Frandsen, S., Bedin, L. R., Milone, A. P., Dotter, A., Feiden, G. A., Stetson, P. B., Sandquist, E., Miglio, A., Stello, D., and Jessen-Hansen, J.

Subjects

HELIUM, OPEN clusters of stars, ECLIPSING binaries, STELLAR mass, SEISMOLOGY

Abstract

Context. Models of stellar structure and evolution can be constrained by measuring accurate parameters of detached eclipsing binaries in open clusters. Multiple binary stars provide the means to determine helium abundances in these old stellar systems, and in turn, to improve estimates of their age. Aims. In the first paper of this series, we demonstrated how measurements of multiple eclipsing binaries in the old open cluster NGC 6791 sets tighter constraints on the properties of stellar models than has previously been possible, thereby potentially improving both the accuracy and precision of the cluster age. Here we add additional constraints and perform an extensive model comparison to determine the best estimates of the cluster age and helium content, employing as many observational constraints as possible. Methods. We improve our photometry and correct empirically for differential reddening effects. We then perform an extensive comparison of the new colour-magnitude diagrams (CMDs) and eclipsing binary measurements to Victoria and DSEP isochrones in order to estimate cluster parameters. We also reanalyse a spectrum of the star 2-17 to improve [Fe/H] constraints. Results. We find a best estimate of the age of ~8.3 Gyr for NGC 6791 while demonstrating that remaining age uncertainty is dominated by uncertainties in the CNO abundances. The helium mass fraction is well constrained at Y = 0.30±0.01 resulting in ΔY/ΔZ ~ 1.4 assuming that such a relation exists. During the analysis we firmly identify blue straggler stars, including the star 2-17, and find indications for the presence of their evolved counterparts. Our analysis supports the RGB mass-loss found from asteroseismology and we determine precisely the absolute mass of stars on the lower RGB, MRGB = 1.15±0.02 M⊙. This will be an important consistency check for the detailed asteroseismology of cluster stars. Conclusions. Using multiple, detached eclipsing binaries for determining stellar cluster ages, it is now possible to constrain parameters of stellar models, notably the helium content, which were previously out of reach. By observing a suitable number of detached eclipsing binaries in several open clusters, it will be possible to calibrate the age-scale and the helium enrichment parameter Δ Y/Δ Z, and provide firm constraints that stellar models must reproduce. [ABSTRACT FROM AUTHOR]

Published

2012

33. Atmospheric parameters of 82 red giants in the Kepler field.

Author

Thygesen, A. O., Frandsen, S., Bruntt, H., Kallinger, T., Andersen, M. F., Elsworth, Y. P., Hekker, S., Karoff, C., Stello, D., Brogaard, K., Burke, C., Caldwell, D. A., and Christiansen, J. L.

Subjects

ASTRONOMY, RED giants, SPECTROGRAPHS, PHOTOMETRY, SPECTRUM analysis

Abstract

Context. Accurate fundamental parameters of stars are essential for the asteroseismic analysis of data from the NASA Kepler mission. Aims. We aim at determining accurate atmospheric parameters and the abundance pattern for a sample of 82 red giants that are targets for the Kepler mission. Methods. We have used high-resolution, high signal-to-noise spectra from three different spectrographs. We used the iterative spectral synthesis method VWA to derive the fundamental parameters from carefully selected high-quality iron lines. After determination of the fundamental parameters, abundances of 13 elements were measured using equivalent widths of the spectral lines. Results. We identify discrepancies in log g and [Fe/H], compared to the parameters based on photometric indices in the Kepler Input Catalogue (larger than 2.0 dex for log g and [Fe/H] for individual stars). The Teff found from spectroscopy and photometry shows good agreement within the uncertainties. We find good agreement between the spectroscopic log g and the log g derived from asteroseismology. Also, we see indications of a potential metallicity effect on the stellar oscillations. Conclusions. We have determined the fundamental parameters and element abundances of 82 red giants. The large discrepancies between the spectroscopic log g and [Fe/H] and values in the Kepler Input Catalogue emphasize the need for further detailed spectroscopic follow-up of the Kepler targets in order to produce reliable results from the asteroseismic analysis. [ABSTRACT FROM AUTHOR]

Published

2012

34. Age and helium content of the open cluster NGC 6791 from multiple eclipsing binary members II. Age dependencies and new insights.

Author

Brogaard, K., VandenBerg, D. A., Bruntt, H., Grundahl, F., Frandsen, S., Bedin, L. R., Milone, A. P., Dotter, A., Feiden, G. A., Stetson, P. B., Sandquist, E., Miglio, A., Stello, D., and Jessen-Hansen, J.

Subjects

EVOLUTIONARY theories, STAR clusters, HELIUM, MAGNITUDE estimation, AGE

Abstract

Context. Models of stellar structure and evolution can be constrained by measuring accurate parameters of detached eclipsing binaries in open clusters. Multiple binary stars provide the means to determine helium abundances in these old stellar systems, and in turn, to improve estimates of their age. Aims. In the first paper of this series, we demonstrated how measurements of multiple eclipsing binaries in the old open cluster NGC6791 sets tighter constraints on the properties of stellar models than has previously been possible, thereby potentially improving both the accuracy and precision of the cluster age. Here we add additional constraints and perform an extensive model comparison to determine the best estimates of the cluster age and helium content, employing as many observational constraints as possible. Methods. We improve our photometry and correct empirically for differential reddening effects. We then perform an extensive comparison of the new colour-magnitude diagrams (CMDs) and eclipsing binary measurements to Victoria and DSEP isochrones in order to estimate cluster parameters. We also reanalyse a spectrum of the star 2-17 to improve [Fe/H] constraints. Results. We find a best estimate of the age of ∼8.3 Gyr for NGC6791 while demonstrating that remaining age uncertainty is dominated by uncertainties in the CNO abundances. The helium mass fraction is well constrained at Y = 0.30 ±0.01 resulting in ΔY/ΔZ ∼ 1.4 assuming that such a relation exists. During the analysis we firmly identify blue straggler stars, including the star 2-17, and find indications for the presence of their evolved counterparts. Our analysis supports the RGB mass-loss found from asteroseismology and we determine precisely the absolute mass of stars on the lower RGB, MRGB = 1.15 ±0.02 M☉. This will be an important consistency check for the detailed asteroseismology of cluster stars. Conclusions. Using multiple, detached eclipsing binaries for determining stellar cluster ages, it is now possible to constrain parameters of stellar models, notably the helium content, which were previously out of reach. By observing a suitable number of detached eclipsing binaries in several open clusters, it will be possible to calibrate the age-scale and the helium enrichment parameter Δ Y/Δ Z, and provide firm constraints that stellar models must reproduce. [ABSTRACT FROM AUTHOR]

Published

2012

35. Evolutionary influences on the structure of red-giant acoustic oscillation spectra from 600d of Kepler observations.

Author

Kallinger, T., Hekker, S., Mosser, B., De Ridder, J., Bedding, T. R., Elsworth, Y. P., Gruberbauer, M., Guenther, D. B., Stello, D., Basu, S., García, R. A., Chaplin, W. J., Mullally, F., Still, M., and Thompson, S. E.

Subjects

RED giants, STELLAR evolution, STELLAR oscillations, DENSITY, KEPLER'S laws, ASTRONOMY

Abstract

Context. It was recently discovered that the period spacings of mixed pressure/gravity dipole modes in red giants permit a distinction between the otherwise unknown evolutionary stage of these stars. The Kepler space mission is reaching continuous observing times long enough to also start studying the fine structure of the observed pressure-mode spectra. Aims. In this paper, we aim to study the signature of stellar evolution on the radial and pressure-dominated l = 2 modes in an ensemble of red giants that show solar-type oscillations. Methods. We use established methods to automatically identify the mode degree of l = 0 and 2 modes and measure the large (Δ νc) and small (Δν02) frequency separation around the central radial mode. We then determine the phase shift ϵc of the central radial mode, i.e. the linear offset in the asymptotic fit to the acoustic modes. Furthermore we measure the individual frequencies of radial modes and investigate their average curvature. Results. We find that ϵc is significantly different for red giants at a given Δ νc but which burn only H in a shell (RGB) than those that have already ignited core He burning. Even though not directly probing the stellar core the pair of local seismic observables (Δ νc, ϵc) can be used as an evolutionary stage discriminator that turned out to be as reliable as the period spacing of the mixed dipole modes.We find a tight correlation between ϵc and Δ νc for RGB stars and unlike less evolved stars we find no indication that ϵc depends on other properties of the star. It appears that the difference in ϵc between the two populations becomes smaller and eventually indistinguishable if we use an average of several radial orders, instead of a local, i.e. only around the central radial mode, large separation to determine the phase shift. This indicates that the information on the evolutionary stage is encoded locally, more precisely in the shape of the radial mode sequence. This shape turns out to be approximately symmetric around the central radial mode for RGB stars but asymmetric for core He burning stars. We computed radial mode frequencies for a sequence of red-giant models and find them to qualitatively confirm our findings. We also find that, at least in our models, the local Δ ν is an at least as good and mostly better proxy for both the asymptotic spacing and the large separation scaled from the model density than the average Δ v. Finally, we investigate the signature of the evolutionary stage on Δν02 and quantify the mass dependency of this seismic parameter. [ABSTRACT FROM AUTHOR]

Published

2012

36. A UNIFORM ASTEROSEISMIC ANALYSIS OF 22 SOLAR-TYPE STARS OBSERVED BY KEPLER.

Author

MATHUR, S., METCALFE, T. S., WOITASZEK, M., BRUNTT, H., VERNER, G. A., CHRISTENSEN-DALSGAARD, J., CREEVEY, O. L., DOĞAN, G., BASU, S., KAROFF, C., STELLO, D., APPOURCHAUX, T., CAMPANTE, T. L., CHAPLIN, W. J., GARCÍA, R. A., BEDDING, T. R., BENOMAR, O., BONANNO, A., DEHEUVELS, S., and ELSWORTH, Y.

Subjects

ASTEROSEISMOLOGY, EXTRASOLAR planets, STELLAR structure, STELLAR mass, STELLAR radiation

Abstract

Asteroseismology with the Kepler space telescope is providing not only an improved characterization of exoplanets and their host stars, but also a new window on stellar structure and evolution for the large sample of solar-type stars in the field. We perform a uniform analysis of 22 of the brightest asteroseismic targets with the highest signal-to- noise ratio observed for 1 month each during the first year of the mission, and we quantify the precision and relative accuracy of asteroseismic determinations of the stellar radius, mass, and age that are possible using various methods. We present the properties of each star in the sample derived from an automated analysis of the individual oscillation frequencies and other observational constraints using the Asteroseismic Modeling Portal (AMP), and we compare them to the results of model-grid-based methods that fit the global oscillation properties. We find that fitting the individual frequencies typically yields asteroseismic radii and masses to ~1% precision, and ages to ~2.5% precision (respectively, 2, 5, and 8 times better than fitting the global oscillation properties). The absolute level of agreement between the results from different approaches is also encouraging, with model-grid-based methods yielding slightly smaller estimates of the radius and mass and slightly older values for the stellar age relative to AMP, which computes a large number of dedicated models for each star. The sample of targets for which this type of analysis is possible will grow as longer data sets are obtained during the remainder of the mission. [ABSTRACT FROM AUTHOR]

Published

2012

37. Asteroseismology of old open clusters with Kepler: direct estimate of the integrated red giant branch mass-loss in NGC 6791 and 6819.

Author

Miglio, A., Brogaard, K., Stello, D., Chaplin, W. J., D'Antona, F., Montalbán, J., Basu, S., Bressan, A., Grundahl, F., Pinsonneault, M., Serenelli, A. M., Elsworth, Y., Hekker, S., Kallinger, T., Mosser, B., Ventura, P., Bonanno, A., Noels, A., Silva Aguirre, V., and Szabo, R.

Subjects

ASTEROSEISMOLOGY, OPEN clusters of stars, RED giants, GALAXIES, SOLAR oscillations, STELLAR luminosity function, COMPARATIVE studies, ASTRONOMICAL photometry, CONSTRAINTS (Physics)

Abstract

ABSTRACT Mass-loss of red giant branch (RGB) stars is still poorly determined, despite its crucial role in the chemical enrichment of galaxies. Thanks to the recent detection of solar-like oscillations in G-K giants in open clusters with Kepler, we can now directly determine stellar masses for a statistically significant sample of stars in the old open clusters NGC 6791 and 6819. The aim of this work is to constrain the integrated RGB mass-loss by comparing the average mass of stars in the red clump (RC) with that of stars in the low-luminosity portion of the RGB [i.e. stars with L≲ L(RC)]. Stellar masses were determined by combining the available seismic parameters νmax and Δν with additional photometric constraints and with independent distance estimates. We measured the masses of 40 stars on the RGB and 19 in the RC of the old metal-rich cluster NGC 6791. We find that the difference between the average mass of RGB and RC stars is small, but significant [ (random) ±0.04 (systematic) M⊙]. Interestingly, such a small does not support scenarios of an extreme mass-loss for this metal-rich cluster. If we describe the mass-loss rate with Reimers prescription, a first comparison with isochrones suggests that the observed is compatible with a mass-loss efficiency parameter in the range 0.1 ≲η≲ 0.3. Less stringent constraints on the RGB mass-loss rate are set by the analysis of the ∼2 Gyr old NGC 6819, largely due to the lower mass-loss expected for this cluster, and to the lack of an independent and accurate distance determination. In the near future, additional constraints from frequencies of individual pulsation modes and spectroscopic effective temperatures will allow further stringent tests of the Δν and νmax scaling relations, which provide a novel, and potentially very accurate, means of determining stellar radii and masses. [ABSTRACT FROM AUTHOR]

Published

2012

38. Fundamental properties of five Kepler stars using global asteroseismic quantities and ground-based observations.

Author

Creevey, O. L., Doğan, G., Frasca, A., Thygesen, A. O., Basu, S., Bhattacharya, J., Biazzo, K., Brandão, I. M., Bruntt, H., Mazumdar, A., Niemczura, E., Shrotriya, T., Sousa, S. G., Stello, D., Subramaniam, A., Campante, T. L., Handberg, R., Mathur, S., Bedding, T. R., and García, R. A.

Subjects

STARS, TIME series analysis, PARAMETERS (Statistics), ASTRONOMICAL observations, ASTRONOMICAL photometry

Abstract

We present an asteroseismic study of the solar-like stars KIC 11395018, KIC 10273246, KIC 10920273, KIC 10339342, and KIC 11234888 using short-cadence time series of more than eight months from the Kepler satellite. For four of these stars, we derive atmospheric parameters from spectra acquired with the Nordic Optical Telescope. The global seismic quantities (average large frequency separation and frequency of maximum power), combined with the atmospheric parameters, yield the mean density and surface gravity with precisions of 2% and ∼0.03 dex, respectively. We also determine the radius, mass, and age with precisions of 2-5%, 7-11%, and ∼35%, respectively, using grid-based analyses. Coupling the stellar parameters with photometric data yields an asteroseismic distance with a precision better than 10%. A v sin i measurement provides a rotational period-inclination correlation, and using the rotational periods from the recent literature, we constrain the stellar inclination for three of the stars. An Li abundance analysis yields an independent estimate of the age, but this is inconsistent with the asteroseismically determined age for one of the stars. We assess the performance of five grid-based analysis methods and find them all to provide consistent values of the surface gravity to ∼0.03 dex when both atmospheric and seismic constraints are at hand. The different grid-based analyses all yield fitted values of radius and mass to within 2.4σ, and taking the mean of these results reduces it to 1.5σ. The absence of a metallicity constraint when the average large frequency separation is measured with a precision of 1% biases the fitted radius and mass for the stars with non-solar metallicity (metal-rich KIC 11395018 and metal-poor KIC 10273246), while including a metallicity constraint reduces the uncertainties in both of these parameters by almost a factor of two. We found that including the average small frequency separation improves the determination of the age only for KIC 11395018 and KIC 11234888, and for the latter this improvement was due to the lack of strong atmospheric constraints. [ABSTRACT FROM AUTHOR]

Published

2012

39. Characterization of the power excess of solar-like oscillations in red giants with Kepler.

Author

Mosser, B., Elsworth, Y., Hekker, S., Huber, D., Kallinger, T., Mathur, S., Belkacem, K., Goupil, M. J., Samadi, R., Barban, C., Bedding, T. R., Chaplin, W. J., García, R. A., Stello, D., De Ridder, J., Middour, C. K., Morris, R. L., and Quintana, E. V.

Subjects

ASTRONOMICAL photometry, KEPLER'S laws, TIME series analysis, RED giants, SOLAR oscillations

Abstract

Context. The space mission Kepler provides us with long and uninterrupted photometric time series of red giants. This allows us to examine their seismic global properties and to compare these with theoretical predictions. Aims. We aim to describe the oscillation power excess observed in red giant oscillation spectra with global seismic parameters, and to investigate empirical scaling relations governing these parameters. From these scalings relations, we derive new physical properties of red giant oscillations. Methods. Various different methods were compared in order to validate the processes and to derive reliable output values. For consistency, a single method was then used to determine scaling relations for the relevant global asteroseismic parameters: mean mode height, mean height of the background signal superimposed on the oscillation power excess, width of the power excess, bolometric amplitude of the radial modes and visibility of non-radial modes. A method for deriving oscillation amplitudes is proposed, which relies on the complete identification of the red giant oscillation spectrum. Results. The comparison of the different methods has shown the important role of the way the background is modelled. The convergence reached by the collaborative work enables us to derive significant results concerning the oscillation power excess. We obtain several scaling relations, and identify the influence of the stellar mass and the evolutionary status. The effect of helium burning on the red giant interior structure is confirmed: it yields a strong mass-radius relation for clump stars. We find that none of the amplitude scaling relations motivated by physical considerations predict the observed mode amplitudes of red giant stars. In parallel, the degree-dependent mode visibility exhibits important variations. Both effects seem related to the significant influence of the high mode mass of non-radial mixed modes. A family of red giants with very weak dipole modes is identified, and its properties are analyzed. Conclusions. The clear correlation between the power densities of the background signal and of the stellar oscillation induces important consequences to be considered for deriving a reliable theoretical relation of the mode amplitude. As a by-product of this work, we have verified that red giant asteroseismology delivers new insights for stellar and Galactic physics, given the evidence for mass loss at the tip of the red giant branch. [ABSTRACT FROM AUTHOR]

Published

2012

40. TESTING SCALING RELATIONS FOR SOLAR-LIKE OSCILLATIONS FROM THE MAIN SEQUENCE TO RED GIANTS USING KEPLER DATA.

Author

Huber, D., Bedding, T. R., Stello, D., Hekker, S., Mathur, S., Mosser, B., Verner, G. A., Bonanno, A., Buzasi, D. L., Campante, T. L., Elsworth, Y. P., Hale, S. J., Kallinger, T., Aguirre, V. Silva, Chaplin, W. J., De Ridder, J., García, R. A., Appourchaux, T., Frandsen, S., and Houdek, G.

Subjects

SOLAR oscillations, STELLAR mass, STELLAR oscillations, ASTRONOMICAL photometry, HR diagrams

Abstract

We have analyzed solar-like oscillations in ~1700 stars observed by the Kepler Mission, spanning from the main sequence to the red clump. Using evolutionary models, we test asteroseismic scaling relations for the frequency of maximum power (vmax), the large frequency separation (Δv), and oscillation amplitudes. We show that the difference of the Δv-vmax relation for unevolved and evolved stars can be explained by different distributions in effective temperature and stellar mass, in agreement with what is expected from scaling relations. For oscillation amplitudes, we show that neither (L/M)s scaling nor the revised scaling relation by Kjeldsen & Bedding is accurate for red-giant stars, and demonstrate that a revised scaling relation with a separate luminosity-mass dependence can be used to calculate amplitudes from the main sequence to red giants to a precision of ~25%. The residuals show an offset particularly for unevolved stars, suggesting that an additional physical dependency is necessary to fully reproduce the observed amplitudes. We investigate correlations between amplitudes and stellar activity, and find evidence that the effect of amplitude suppression is most pronounced for subgiant stars. Finally, we test the location of the cool edge of the instability strip in the Hertzsprung-Russell diagram using solar-like oscillations and find the detections in the hottest stars compatible with a domain of hybrid stochastically excited and opacity driven pulsation. [ABSTRACT FROM AUTHOR]

Published

2011

41. MODELING KEPLER OBSERVATIONS OF SOLAR-LIKE OSCILLATIONS IN THE RED GIANT STAR HD 186355.

Author

Jiang, C., Jiang, B. W., Christensen-Dalsgaard, J., Bedding, T. R., Stello, D., Huber, D., Frandsen, S., Kjeldsen, H., Karoff, C., Mosser, B., Demarque, P., Fanelli, M. N., Kinemuchi, K., and Mullally, F.

Subjects

SOLAR oscillations, RED giants, STELLAR luminosity function, STELLAR evolution

Abstract

We have analyzed oscillations of the red giant star HD 186355 observed by the NASA Kepler satellite. The data consist of the first five quarters of science operations of Kepler, which cover about 13 months. The high-precision time-series data allow us to accurately extract the oscillation frequencies from the power spectrum. We find that the frequency of the maximum oscillation power, vmax, and the mean large frequency separation, Δv, are around 106 and 9.4 µHz, respectively. A regular pattern of radial and non-radial oscillation modes is identified by stacking the power spectra in an echelle diagram. We use the scaling relations of Δv and vmax to estimate the preliminary asteroseismic mass, which is confirmed with the modeling result (M = 1.45 ± 0.05 M⊙) using the Yale Rotating stellar Evolution Code (YREC7). In addition, we constrain the effective temperature, luminosity, and radius from comparisons between observational constraints and models. A number of mixed 1 = 1 modes are also detected and taken into account in our model comparisons. We find a mean observational period spacing for these mixed modes of about 58 s, suggesting that this red giant branch star is in the shell hydrogen-burning phase. [ABSTRACT FROM AUTHOR]

Published

2011

42. GRANULATION IN RED GIANTS: OBSERVATIONS BY THE KEPLER MISSION AND THREE-DIMENSIONAL CONVECTION SIMULATIONS.

Author

MATHUR, S., HEKKER, S., TRAMPEDACH, R., BALLOT, J., KALLINGER, T., BUZASI, D., GARCÍA, R. A., HUBER, D., JIMÉNEZ, A., MOSSER, B., BEDDING, T. R., ELSWORTH, Y., RÉGULO, C., STELLO, D., CHAPLIN, W. J., DE RIDDER, J., HALE, S. J., KINEMUCHI, K., KJELDSEN, H., and MULLALLY, F.

Subjects

SOLAR granulation, RED giant spectra, ASTRONOMICAL observations, KEPLER'S laws, CONVECTION (Astrophysics), SIMULATION methods & models

Abstract

The granulation pattern that we observe on the surface of the Sun is due to hot plasma rising to the photosphere where it cools down and descends back into the interior at the edges of granules. This is the visible manifestation of convection taking place in the outer part of the solar convection zone. Because red giants have deeper convection zones than the Sun, we cannot a priori assume that their granulation is a scaled version of solar granulation. Until now, neither observations nor one-dimensional analytical convection models could put constraints on granulation in red giants. With asteroseismology, this study can now be performed. We analyze ~1000 red giants that have been observed by Kepler during 13 months. We fit the power spectra with Harvey-like profiles to retrieve the characteristics of the granulation (timescale τgran and power Pgran). We search for a correlation between these parameters and the global acoustic-mode parameter (the position of maximum power, vmax) as well as with stellar parameters (mass, radius, surface gravity (log g), and effective temperature (Teff)). We show that τeff Due to image rights restrictions, multiple line equation(s) cannot be graphically displayed., and Pgran Due to image rights restrictions, multiple line equation(s) cannot be graphically displayed., which is consistent with the theoretical predictions. We find that the granulation timescales of stars that belong to the red clump have similar values while the timescales of stars in the red giant branch are spread in a wider range. Finally, we show that realistic three-dimensional simulations of the surface convection in stars, spanning the (Teff, log g) range of our sample of red giants, match the Kepler observations well in terms of trends. [ABSTRACT FROM AUTHOR]

Published

2011

43. The excitation of solar-like oscillations in a ??Sct star by efficient envelope convection.

Author

Antoci, V., Handler, G., Campante, T. L., Thygesen, A. O., Moya, A., Kallinger, T., Stello, D., Grigahcène, A., Kjeldsen, H., Bedding, T. R., Lüftinger, T., Christensen-Dalsgaard, J., Catanzaro, G., Frasca, A., De Cat, P., Uytterhoeven, K., Bruntt, H., Houdek, G., Kurtz, D. W., and Lenz, P.

Subjects

PULSATING stars, KEPLER'S conjecture, HELIUM, IONIZATION (Atomic physics), SOLAR oscillations, STELLAR oscillations

Abstract

Delta Scuti (??Sct) stars are opacity-driven pulsators with masses of 1.5-2.5M?, their pulsations resulting from the varying ionization of helium. In less massive stars such as the Sun, convection transports mass and energy through the outer 30?per cent of the star and excites a rich spectrum of resonant acoustic modes. Based on the solar example, with no firm theoretical basis, models predict that the convective envelope in ??Sct stars extends only about 1?per cent of the radius, but with sufficient energy to excite solar-like oscillations. This was not observed before the Kepler mission, so the presence of a convective envelope in the models has been questioned. Here we report the detection of solar-like oscillations in the ??Sct star HD?187547, implying that surface convection operates efficiently in stars about twice as massive as the Sun, as the ad hoc models predicted. [ABSTRACT FROM AUTHOR]

Published

2011

44. Global asteroseismic properties of solar-like oscillations observed by Kepler: a comparison of complementary analysis methods.

Author

Verner, G. A., Elsworth, Y., Chaplin, W. J., Campante, T. L., Corsaro, E., Gaulme, P., Hekker, S., Huber, D., Karoff, C., Mathur, S., Mosser, B., Appourchaux, T., Ballot, J., Bedding, T. R., Bonanno, A., Broomhall, A.-M., García, R. A., Handberg, R., New, R., and Stello, D.

Subjects

ASTEROSEISMOLOGY, SOLAR oscillations, SUBGIANT stars, STELLAR oscillations, TEMPERATURE of stars, INSTABILITY strip (Astrophysics)

Abstract

ABSTRACT We present the asteroseismic analysis of 1948 F-, G- and K-type main-sequence and subgiant stars observed by the National Aeronautics and Space Administration Kepler mission. We detect and characterize solar-like oscillations in 642 of these stars. This represents the largest cohort of main-sequence and subgiant solar-like oscillators observed to date. The photometric observations are analysed using the methods developed by nine independent research teams. The results are combined to validate the determined global asteroseismic parameters and calculate the relative precision by which the parameters can be obtained. We correlate the relative number of detected solar-like oscillators with stellar parameters from the Kepler Input Catalogue and find a deficiency for stars with effective temperatures in the range 5300 ≲ Teff≲ 5700 K and a drop-off in detected oscillations in stars approaching the red edge of the classical instability strip. We compare the power-law relationships between the frequency of peak power, νmax, the mean large frequency separation, Δν, and the maximum mode amplitude, Amax, and show that there are significant method-dependent differences in the results obtained. This illustrates the need for multiple complementary analysis methods to be used to assess the robustness and reproducibility of results derived from global asteroseismic parameters. [ABSTRACT FROM AUTHOR]

Published

2011

45. Solar-like oscillations from the depths of the red-giant star KIC 4351319 observed with Kepler.

Author

Di Mauro, M. P., Cardini, D., Catanzaro, G., Ventura, R., Barban, C., Bedding, T. R., Christensen-Dalsgaard, J., De Ridder, J., Hekker, S., Huber, D., Kallinger, T., Miglio, A., Montalban, J., Mosser, B., Stello, D., Uytterhoeven, K., Kinemuchi, K., Kjeldsen, H., Mullally, F., and Still, M.

Subjects

RED giant spectra, SOLAR oscillations, ARTIFICIAL satellites, ASTRONOMICAL observations, SIGNAL-to-noise ratio, STELLAR mass, TEMPERATURE of stars

Abstract

ABSTRACT We present the results of the asteroseismic analysis of the red-giant star KIC 4351319 (TYC 3124-914-1), observed for 30 d in short-cadence mode with the Kepler satellite. The analysis has allowed us to determine the large and small frequency separations, Hz and Hz, respectively, and the frequency of maximum oscillation power, Hz. The high signal-to-noise ratio of the observations allowed us to identify 25 independent pulsation modes whose frequencies range approximately from 300 to Hz. The observed oscillation frequencies together with the accurate determination of the atmospheric parameters (effective temperature, gravity and metallicity), provided by additional ground-based spectroscopic observations, enabled us to theoretically interpret the observed oscillation spectrum. KIC 4351319 appears to oscillate with a well-defined solar-type p-mode pattern due to radial acoustic modes and non-radial nearly pure p modes. In addition, several non-radial mixed modes have been identified. Theoretical models well reproduce the observed oscillation frequencies and indicate that this star, located at the base of the ascending red-giant branch, is in the hydrogen-shell-burning phase, with a mass of ∼1.3 M⊙, a radius of and an age of ∼5.6 Gyr. The main parameters of this star have been determined with an unprecedented level of precision for a red-giant star, with uncertainties of 2 per cent for mass, 7 per cent for age, 1 per cent for radius and 4 per cent for luminosity. [ABSTRACT FROM AUTHOR]

Published

2011

46. Variability in mode amplitudes in the rapidly oscillating Ap star HR 1217.

Author

White, T. R., Bedding, T. R., Stello, D., Kurtz, D. W., Cunha, M. S., and Gough, D. O.

Subjects

PECULIAR stars, STELLAR oscillations, STELLAR magnetic fields, STAR observations, STELLAR rotation, WAVELETS (Mathematics), DATA analysis

Abstract

BSTRACT HR 1217 is one of the best studied rapidly oscillating Ap stars with eight known oscillation modes that are distorted by a strong, global magnetic field. We have reanalysed the multisite observations of HR 1217 taken in 1986 and 2000. We determined a weighting scheme for the 1986 and 2000 data to minimize the noise level. A wavelet analysis of the data has found that the modulation of the amplitude due to rotation for all frequencies is, in general, consistent with the expected modulation for modified ℓ= 1, 2 or 3 modes. Unexpected variations in the rotational modulation are also seen, with variations in the modulation profile, time of maximal pulsation and pulsational energy in each mode. Interestingly, these changes take place on a short time-scale, of the order of days. We consider potential explanations for these behaviours. [ABSTRACT FROM AUTHOR]

Published

2011

47. Characterization of red giant stars in the public Kepler data.

Author

Hekker, S., Gilliland, R. L., Elsworth, Y., Chaplin, W. J., De Ridder, J., Stello, D., Kallinger, T., Ibrahim, K. A., Klaus, T. C., and Li, J.

Subjects

RED giants, KEPLER'S laws, STELLAR oscillations, ASTRONOMICAL photometry, STELLAR luminosity function, ASTRONOMY

Abstract

The first public release of long-cadence stellar photometric data collected by the NASA Kepler mission has now been made available. In this paper, we characterize the red giant (G-K) stars in this large sample in terms of their solar-like oscillations. We use published methods and well-known scaling relations in the analysis. Just over 70 per cent of the red giants in the sample show detectable solar-like oscillations, and from these oscillations we are able to estimate the fundamental properties of the stars. This asteroseismic analysis reveals different populations: low-luminosity H-shell burning red giant branch stars, cool high-luminosity red giants on the red giant branch and He-core burning clump and secondary-clump giants. [ABSTRACT FROM AUTHOR]

Published

2011

48. Preparation of Kepler light curves for asteroseismic analyses.

Author

García, R. A., Hekker, S., Stello, D., Gutiérrez-Soto, J., Handberg, R., Huber, D., Karoff, C., Uytterhoeven, K., Appourchaux, T., Chaplin, W. J., Elsworth, Y., Mathur, S., Ballot, J., Christensen-Dalsgaard, J., Gilliland, R. L., Houdek, G., Jenkins, J. M., Kjeldsen, H., McCauliff, S., and Metcalfe, T.

Subjects

ASTEROSEISMOLOGY, KEPLER'S laws, LIGHT curves, ASTRONOMICAL photometry, PULSATING stars, STELLAR oscillations, DATA analysis

Abstract

The Kepler mission is providing photometric data of exquisite quality for the asteroseismic study of different classes of pulsating stars. These analyses place particular demands on the pre-processing of the data, over a range of time-scales from minutes to months. Here, we describe processing procedures developed by the Kepler Asteroseismic Science Consortium to prepare light curves that are optimized for the asteroseismic study of solar-like oscillating stars in which outliers, jumps and drifts are corrected. [ABSTRACT FROM AUTHOR]

Published

2011

49. Cepheid investigations using the Kepler space telescope.

Author

Szabó, R., Szabados, L., Ngeow, C.-C., Smolec, R., Derekas, A., Moskalik, P., Nuspl, J., Lehmann, H., Fűrész, G., Molenda-Żakowicz, J., Bryson, S. T., Henden, A. A., Kurtz, D. W., Stello, D., Nemec, J. M., Benkő, J. M., Berdnikov, L., Bruntt, H., Evans, N. R., and Gorynya, N. A.

Subjects

CEPHEIDS, SPACE telescopes, ASTRONOMICAL photometry, FLARE stars, SPECTRUM analysis, MEASUREMENT, STELLAR magnitudes, PULSATING stars

Abstract

We report results of initial work done on selected candidate Cepheids to be observed with the Kepler space telescope. Prior to the launch, 40 candidates were selected from previous surveys and data bases. The analysis of the first 322 d of Kepler photometry, and recent ground-based follow-up multicolour photometry and spectroscopy allowed us to confirm that one of these stars, V1154 Cyg (KIC 7548061), is indeed a 4.9-d Cepheid. Using the phase lag method, we show that this star pulsates in the fundamental mode. New radial velocity data are consistent with previous measurements, suggesting that a long-period binary component is unlikely. No evidence is seen in the ultraprecise, nearly uninterrupted Kepler photometry for non-radial or stochastically excited modes at the micromagnitude level. The other candidates are not Cepheids, but an interesting mix of possible spotted stars, eclipsing systems and flare stars. [ABSTRACT FROM AUTHOR]

Published

2011

50. ASTEROSEISMOLOGY OF RED GIANTS FROM THE FIRST FOUR MONTHS OF KEPLER DATA: GLOBAL OSCILLATION PARAMETERS FOR 800 STARS.

Author

Huber, D., Bedding, T. R., Stello, D., Mosser, B., Mathur, S., Kallinger, T., Hekker, S., Elsworth, Y. P., Buzasi, D. L., Ridder, J. De, Gilliland, R. L., Kjeldsen, H., Chaplin, W. J., García, R. A., Hale, S. J., Preston, H. L., White, T. R., Borucki, W. J., Christensen-Dalsgaard, J., and Clarke, B. D.

Published

2010