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

Corsaro, E.; Mathur, S.; García, R. A.; Gaulme, P.; Pinsonneault, Marc H.; Stassun, Keivan G.; Stello, Dennis; Tayar, Jamie; Trampedach, Regner; Jiang, Chen; Nitschelm, Christian; Salabert, D.

doi:10.1051/0004-6361/201731094

Cited by 57 publications

(85 citation statements)

References 72 publications

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“…Note today, that this often described by a linear combination of Lorentzian and super-Lorentzian functions (as done in Paper II); at least two components are necessary to adequately fit the background signal from the granulation phenomena in empirical power spectra, though we highlight that the physical origin for a component on the mesoscale (not discussed here) remains an open question (e.g. see Matloch et al 2010;Kallinger et al 2014;Corsaro et al 2017;Rincon & Rieutord 2018;Kessar et al 2019, and references therein). Such an approach provides a characteristic timescale, τ , and a corresponding disc-integrated rms for each phenomenon, σ.…”

Section: Comparison To Solar Observationsmentioning

confidence: 94%

Stellar Surface Magnetoconvection as a Source of Astrophysical Noise. III. Sun-as-a-Star Simulations and Optimal Noise Diagnostics

Cegla

Watson

Shelyag

et al. 2019

ApJ

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Stellar surface magnetoconvection (granulation) creates asymmetries in the observed stellar absorption lines that can subsequently manifest themselves as spurious radial velocities shifts. In turn, this can then mask the Doppler-reflex motion induced by orbiting planets on their host stars, and represents a particular challenge for determining the masses of low-mass, long-period planets. Herein, we study this impact by creating Sun-as-a-star observations that encapsulate the granulation variability expected from 3D magnetohydrodynamic simulations. These Sun-as-a-star model observations are in good agreement with empirical observations of the Sun, but may underestimate the total variability relative to the quiet Sun due to the increased magnetic field strength in our models. We find numerous line profile characteristics linearly correlate with the disc-integrated convection-induced velocities. Removing the various correlations with the line bisector, equivalent width, and the V asy indicator may reduce ∼50-60% of the granulation noise in the measured velocities. We also find that simultaneous photometry may be a key diagnostic, as our proxy for photometric brightness also allowed us to remove ∼50% of the granulation-induced radial velocity noise. These correlations and granulation-noise mitigations breakdown in the presence of low instrumental resolution and/or increased stellar rotation, as both act to smooth the observed line profile asymmetries.

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Section: Comparison To Solar Observationsmentioning

confidence: 94%

Stellar Surface Magnetoconvection as a Source of Astrophysical Noise. III. Sun-as-a-Star Simulations and Optimal Noise Diagnostics

Cegla

Watson

Shelyag

et al. 2019

ApJ

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“…The typical amplitudes and turnover timescales of surface granulation depend on the stellar parameters. Amplitudes increase with effective temperature (and possibly the stellar metallicity; see Corsaro et al 2017) and decrease with decreasing stellar mass and/or increasing surface gravity (Svensson & Ludwig 2005). Both decrease with increasing mean oscillation frequency ν max (Dravins 1988;Kallinger et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Mitigating flicker noise in high-precision photometry

Sulis

Lendl

Hofmeister

et al. 2020

A&A

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Context. In photometry, the short-timescale stellar variability (“flicker”), such as that caused by granulation and solar-like oscillations, can reach amplitudes comparable to the transit depth of Earth-sized planets and is correlated over the typical transit timescales. It can introduce systematic errors on the inferred planetary parameters when a small number of transits are observed. Aims. The objective of this paper is to characterize the statistical properties of the flicker noise and quantify its impact on the inferred transit parameters. Methods. We used the extensive solar observations obtained with SoHO/VIRGO to characterize flicker noise. We simulated realistic transits across the solar disk using SDO/HMI data and used these to obtain transit light curves, which we used to estimate the errors made on the transit parameters due to the presence of real solar noise. We make these light curves publicly available. To extend the study to a wider parameter range, we derived the properties of flicker noise using Kepler observations and studied their dependence on stellar parameters. Finally, we predicted the limiting stellar apparent magnitude for which the properties of the flicker noise can be extracted using high-precision CHEOPS and PLATO observations. Results. Stellar granulation is a stochastic colored noise, and is stationary with respect to the stellar magnetic cycle. Both the flicker correlation timescales and amplitudes increase with the stellar mass and radius. If these correlations are not taken into account when fitting for the parameters of transiting exoplanets, this can bias the inferred parameters. In particular, we find errors of up to 10% on the ratio between the planetary and stellar radius (Rp∕Rs) for an Earth-sized planet orbiting a Sun-like star. Conclusions. Flicker will significantly affect the inferred parameters of transits observed at high precision with CHEOPS and PLATO for F and G stars. Dedicated modeling strategies need to be developed to accurately characterize both the star and the transiting exoplanets.

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“…The detection of oscillations in thousands of stars has led to breakthroughs such as the discovery of rapidly rotating cores in subgiants and red giants, as well as the systematic measurement of stellar masses, radii, and ages (see Chaplin & Miglio 2013 for a review). Asteroseismology has also become the "gold standard" for calibrating more indirect methods to determine stellar parameters such as surface gravity (log g) from spectroscopy (Petigura et al 2017a) and stellar granulation (Mathur et al 2011;Bastien et al 2013;Kallinger et al 2016;Corsaro et al 2017;Bugnet et al 2018;Pande et al 2018), and age from rotation periods (gyrochronology; e.g., García et al 2014;van Saders et al 2016).…”

Section: Introductionmentioning

confidence: 99%

A Hot Saturn Orbiting an Oscillating Late Subgiant Discovered by TESS

Huber

Chaplin

Chontos

et al. 2019

Self Cite

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We present the discovery of HD 221416 b, the first transiting planet identified by the Transiting Exoplanet Survey Satellite (TESS) for which asteroseismology of the host star is possible. HD 221416 b (HIP 116158, TOI-197) is a bright (V=8.2 mag), spectroscopically classified subgiant that oscillates with an average frequency of about 430 μHz and displays a clear signature of mixed modes. The oscillation amplitude confirms that the redder TESS bandpass compared to Kepler has a small effect on the oscillations, supporting the expected yield of thousands of solar-like oscillators with TESS 2 minute cadence observations. Asteroseismic modeling yields a robust determination of the host star radius (R å =2.943±0.064 R e), mass (M å =1.212±0.074 M e), and age (4.9±1.1 Gyr), and demonstrates that it has just started ascending the red-giant branch. Combining asteroseismology with transit modeling and radial-velocity observations, we show that the planet is a "hot Saturn" (R p =9.17±0.33 R ⊕) with an orbital period of ∼14.3 days, irradiance of F=343±24 F ⊕ , and moderate mass (M p =60.5±5.7 M ⊕) and density (ρ p =0.431±0.062 g cm −3). The properties of HD 221416 b show that the host-star metallicity-planet mass correlation found in sub-Saturns (4-8 R ⊕) does not extend to larger radii, indicating that planets in the transition between sub-Saturns and Jupiters follow a relatively narrow range of densities. With a density measured to ∼15%, HD 221416 b is one of the best characterized Saturn-size planets to date, augmenting the small number of known transiting planets around evolved stars and demonstrating the power of TESS to characterize exoplanets and their host stars using asteroseismology.

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

Cited by 57 publications

References 72 publications

Stellar Surface Magnetoconvection as a Source of Astrophysical Noise. III. Sun-as-a-Star Simulations and Optimal Noise Diagnostics

Stellar Surface Magnetoconvection as a Source of Astrophysical Noise. III. Sun-as-a-Star Simulations and Optimal Noise Diagnostics

Mitigating flicker noise in high-precision photometry

A Hot Saturn Orbiting an Oscillating Late Subgiant Discovered by TESS

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