The Rotation of M Dwarfs Observed by the Apache Point Galactic Evolution Experiment

Gilhool, Steven; Blake, Cullen H.; Terrien, Ryan C.; Bender, Chad F.; Mahadevan, Suvrath; Deshpande, Rohit

doi:10.3847/1538-3881/aa9c7c

Cited by 12 publications

(9 citation statements)

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“…A number of studies out of the M-dwarf ancillary survey have already been conducted to measure reliable fundamental atmospheric parameters and make kinematic measurements using spectral synthesis of atmo-spheric model grids. These studies include Deshpande et al (2013) and Gilhool et al (2018) which have studied the radial and rotational kinematics for 700+ sources; Souto et al (2017) and Souto et al (2018) which have modeled three exoplanet-hosting M dwarfs , determining T eff /log g/metallicity + 13 elemental abundances; Rajpurohit et al (2018) which tested BT-Settl Allard et al (2012) and MARCS Gustafsson et al (2008) model grids on 45 M dwarfs to estimate T eff /log g/metallicity; and Skinner et al (2018) which identified and measured mass ratios and radial velocities for 44 M-dwarf spectroscopic binaries. This work complements existing studies by producing a model-independent catalog of spectroscopic temperatures and metallicities to test against model predictions for the entire APOGEE M-dwarf sample, which we quantify to contain at least 10,000 sources to date (DR14).…”

Section: Datamentioning

confidence: 99%

Temperatures and Metallicities of M Dwarfs in the APOGEE Survey

Birky

Mann

Burgasser

2020

ApJ

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M dwarfs have enormous potential for our understanding of structure and formation on both Galactic and exoplanetary scales through their properties and compositions. However, current atmosphere models have limited ability to reproduce spectral features in stars at the coolest temperatures (T eff < 4200 K) and to fully exploit the information content of current and upcoming large-scale spectroscopic surveys. Here we present a catalog of spectroscopic temperatures, metallicities, and spectral types for 5875 M dwarfs in the Apache Point Observatory Galactic Evolution Experiment (APOGEE) and Gaia-DR2 surveys using The Cannon: a flexible, data-driven spectral-modeling and parameterinference framework demonstrated to estimate stellar-parameter labels (T eff , log g, [Fe/H], and detailed abundances) to high precision. Using a training sample of 87 M dwarfs with optically derived labels spanning 2860 < T eff < 4130 K calibrated with bolometric temperatures, and −0.5 < [Fe/H] < 0.5 dex calibrated with FGK binary metallicities, we train a two-parameter model with predictive accuracy (in cross-validation) to 77 K and 0.09 dex respectively. We also train a one-dimensional spectral classification model using 51 M dwarfs with Sloan Digital Sky Survey optical spectral types ranging from M0 to M6, to predictive accuracy of 0.7 types. We find Cannon temperatures to be in agreement to within 60 K compared to a subsample of 1702 sources with color-derived temperatures, and Cannon metallicities to be in agreement to within 0.08 dex metallicity compared to a subsample of 15 FGK+M or M+M binaries. Finally, our comparison between Cannon and APOGEE pipeline (ASPCAP DR14) labels finds that ASPCAP is systematically biased toward reporting higher temperatures and lower metallicities for M dwarfs.

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Section: Datamentioning

confidence: 99%

Temperatures and Metallicities of M Dwarfs in the APOGEE Survey

Birky

Mann

Burgasser

2020

ApJ

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“…These rapidly-rotating stars can be significantly oblate due to the centrifugal force pulling the equator outwards. Additionally, pre-main sequence stars and some young main sequence M dwarfs have been shown to display very rapid rotation (Rebull et al 2016(Rebull et al , 2017(Rebull et al , 2018(Rebull et al , 2020Stauffer et al 2018;Gilhool et al 2018) and are therefore also likely to be oblate. Other kinds of stars such as binary stars and exoplanet hosts may also exhibit deviations from spherical geometry due to tidal forces in addition to rotation (Prša 2018;Welsh et al 2010).…”

Section: Introductionmentioning

confidence: 99%

Efficient and precise transit light curves for rapidly-rotating, oblate stars

Dholakia,

Luger,

Dholakia

2021

Preprint

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We derive solutions to transit light curves of exoplanets orbiting rapidly-rotating stars. These stars exhibit significant oblateness and gravity darkening, a phenomenon where the poles of the star have a higher temperature and luminosity than the equator. Light curves for exoplanets transiting these stars can exhibit deviations from those of slowly-rotating stars, even displaying significantly asymmetric transits depending on the system's spin-orbit angle. As such, these phenomena can be used as a protractor to measure the spin-orbit alignment of the system. In this paper, we introduce a novel semi-analytic method for generating model light curves for gravity-darkened and oblate stars with transiting exoplanets. We implement the model within the code package starry and demonstrate several orders of magnitude improvement in speed and precision over existing methods. We test the model on a TESS light curve of WASP-33, whose host star displays rapid rotation (v sin i * = 86.4 km/s). We subtract the host's δ-Scuti pulsations from the light curve, finding an asymmetric transit characteristic of gravity darkening. We find the projected spin orbit angle is consistent with Doppler tomography and constrain the true spin-orbit angle of the system as ϕ = 108.3 +19.0 −15.4• . We demonstrate the method's uses in constraining spin-orbit inclinations of such systems photometrically with posterior inference. Lastly, we note the use of such a method for inferring the dynamical history of thousands of such systems discovered by TESS.

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“…With TESS now beginning to survey the northern hemisphere, the study presented here is particularly timely, as all of the bright M dwarfs in the sample objective of this work are prime targets for the potential identification of transiting small planets amenable to high-precision mass determination and further atmospheric characterization measurements (TESS mission Level 1 Requirement). Our sample of rotation periods can also be used to further our understanding of important issues of stellar astrophysics pertaining to partly and fully convective stars, such as differences in rotational evolution (e.g., Gilhool et al 2018, and references therein) and the age-rotation-activity relation (e.g., Wright et al 2018;González-Álvarez et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Photometric rotation periods for 107 M dwarfs from the APACHE survey

Giacobbe

Benedetto

Damasso

et al. 2019

Monthly Notices of the Royal Astronomical Society

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We present rotation period measurements for 107 M dwarfs in the mass range 0.15 − 0.70M ⊙ observed within the context of the APACHE photometric survey. We measure rotation periods in the range 0.5-190 days, with the distribution peaking at ∼ 30 days. We revise the stellar masses and radii for our sample of rotators by exploiting the Gaia DR2 data. For ∼ 20% of the sample, we compare the photometric rotation periods with those derived from different spectroscopic indicators, finding good correspondence in most cases. We compare our rotation periods distribution to the one obtained by the Kepler survey in the same mass range, and to that derived by the MEarth survey for stars in the mass range 0.07 − 0.25M ⊙ . The APACHE and Kepler periods distributions are in good agreement, confirming the reliability of our results, while the APACHE distribution is consistent with the MEarth result only for the older/slow rotators, and in the overlapping mass range of the two surveys. Combining the APACHE/Kepler distribution with the MEarth distribution, we highlight that the rotation period increases with decreasing stellar mass, in agreement with previous work. Our findings also suggest that the spin-down time scale, from fast to slow rotators, changes crossing the fully convective limit at ≈ 0.3M ⊙ for M dwarfs. The catalogue of 107 rotating M dwarfs presented here is particularly timely, as the stars are prime targets for the potential identification of transiting small planets with TESS and amenable to high-precision mass determination and further atmospheric characterization measurements.

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The Rotation of M Dwarfs Observed by the Apache Point Galactic Evolution Experiment

Cited by 12 publications

References 54 publications

Temperatures and Metallicities of M Dwarfs in the APOGEE Survey

Temperatures and Metallicities of M Dwarfs in the APOGEE Survey

Efficient and precise transit light curves for rapidly-rotating, oblate stars

Photometric rotation periods for 107 M dwarfs from the APACHE survey

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