Why Are Rapidly Rotating M Dwarfs in the Pleiades So (Infra)red? New Period Measurements Confirm Rotation-Dependent Color Offsets From the Cluster Sequence

Covey, Kevin R.; Agüeros, Marcel A.; Law, Nicholas M.; Liu, Jiyu; Ahmadi, A.; Laher, Russ R.; Levitan, David; Sesar, Branimir; Surace, J.

doi:10.3847/0004-637x/822/2/81

Cited by 50 publications

(60 citation statements)

References 72 publications

(114 reference statements)

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“…This hypothesis is supported by the work of Kamai et al (2014): these authors found a positive correlation between rotation rate and color abnormality, suggesting that the most rapidly rotating, and thus perhaps the most heavily spotted stars, show the greatest abnormalities. A rotation-color correlation was later demonstrated for the stars less massive than spectral-type K by Covey et al (2016). Moreover, Somers & Stassun (2017) found a connection between rotation rate and radius inflation within this cluster, signifying that magnetic activity is likely influencing the structure of these K-dwarfs.…”

Section: The K-dwarfs Of the Pleiadesmentioning

confidence: 82%

The SPOTS Models: A Grid of Theoretical Stellar Evolution Tracks and Isochrones for Testing the Effects of Starspots on Structure and Colors

Somers

Cao

Pinsonneault

2020

ApJ

109

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One-dimensional stellar evolution models have been successful at representing the structure and evolution of stars in diverse astrophysical contexts, but complications have been noted in the context of young, magnetically active stars, as well as close binary stars with significant tidal interactions. Numerous puzzles are associated with pre-main sequence and active main-sequence stars, relating to their radii, their colors, certain elemental abundances, and the coevality of young clusters, among others. A promising explanation for these puzzles is the distorting effects of magnetic activity and starspots on the structure of active stars. To assist the community in evaluating this hypothesis, we present the Stellar Parameters Of Tracks with Starspots (SPOTS) models, a grid of solar-metallicity stellar evolutionary tracks and isochrones which include a treatment of the structural effects of starspots. The models range from 0.1-1.3M and from spot-less to a surface covering fraction of 85%, and are evolved from the pre-main sequence to the red giant branch (or 15 Gyr). We also produce two-temperature synthetic colors for our models using empirically-calibrated color tables. We describe the physical ingredients included in the SPOTS models and compare their predictions to other modern evolution codes. Finally, we apply these models to several open questions in the field of active stars, including the radii of young eclipsing binaries, the color scale of pre-main sequence stars, and the existence of sub-subgiants, demonstrating that our models can explain many peculiar features of active stars.

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Section: The K-dwarfs Of the Pleiadesmentioning

confidence: 82%

The SPOTS Models: A Grid of Theoretical Stellar Evolution Tracks and Isochrones for Testing the Effects of Starspots on Structure and Colors

Somers

Cao

Pinsonneault

2020

ApJ

109

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“…For example, anomalous colors of K dwarfs in the Pleiades can be explained by ∼50% fill factors of spots (Stauffer et al 2003), while LAMOST spectra of the TiO band indicates that ∼ 30% spot coverages may be common for 3500-5000 K stars (Fang et al 2016). Recent photometric monitoring of the Pleiades indicates that the anomalous colors scale with rotation rate, strengthing the case for magnetic-field induced starspots as the cause of the anomaly (Covey et al 2016). However, the Covey et al (2016) Pleiades rotation rates do not scale with the ∆V photometric amplitude at the precision of the PTF data, suggesting that while the overall starspot coverage increases with rotation rate, the longitudinally asymmetric component does not.…”

Section: Discussionmentioning

confidence: 99%

“…Recent photometric monitoring of the Pleiades indicates that the anomalous colors scale with rotation rate, strengthing the case for magnetic-field induced starspots as the cause of the anomaly (Covey et al 2016). However, the Covey et al (2016) Pleiades rotation rates do not scale with the ∆V photometric amplitude at the precision of the PTF data, suggesting that while the overall starspot coverage increases with rotation rate, the longitudinally asymmetric component does not. LkCa 4 represents an example of such an architecture, with more than 50% of the visible stellar surface covered in spots at all observational phases.…”

Section: Discussionmentioning

confidence: 99%

Placing the Spotted T Tauri Star LkCa 4 on an HR Diagram

Gully-Santiago

Herczeg

Czekala

et al. 2017

ApJ

Self Cite

131

111

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Ages and masses of young stars are often estimated by comparing their luminosities and effective temperatures to pre-main sequence stellar evolution tracks, but magnetic fields and starspots complicate both the observations and evolution. To understand their influence, we study the heavily-spotted weak-lined T-Tauri star LkCa 4 by searching for spectral signatures of radiation originating from the starspot or starspot groups. We introduce a new methodology for constraining both the starspot filling factor and the spot temperature by fitting two-temperature stellar atmosphere models constructed from Phoenix synthetic spectra to a high-resolution near-IR IGRINS spectrum. Clearly discernable spectral features arise from both a hot photospheric component T hot ∼ 4100 K and to a cool component T cool ∼ 2700 − 3000 K, which covers ∼ 80% of the visible surface. This mix of hot and cool emission is supported by analyses of the spectral energy distribution, rotational modulation of colors and of TiO band strengths, and features in low-resolution optical/near-IR spectroscopy. Although the revised effective temperature and luminosity make LkCa 4 appear much younger and lower mass than previous estimates from unspotted stellar evolution models, appropriate estimates will require the production and adoption of spotted evolutionary models. Biases from starspots likely afflict most fully convective young stars and contribute to uncertainties in ages and age spreads of open clusters. In some spectral regions starspots act as a featureless "veiling" continuum owing to high rotational broadening and heavy line-blanketing in cool star spectra. Some evidence is also found for an anti-correlation between the velocities of the warm and cool components.

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“…Hartman et al (2011) measure a period of 11.2days for 2M2236+4751; compared to the Pleaides rotation distribution, which has a comparable age to AB Dor and a well characterized stellar population, this period sits near the maximum envelope of rotation rates for stellar masses of ≈0.6M e (Hartman et al 2010;Covey et al 2016;Rebull et al 2016). K7 members in AB Dor exhibit a similarly broad range of rotation periods from 0.4-9.3 days (Table 3).…”

Section: Age and Young Moving Group Membershipmentioning

confidence: 99%

Planets Around Low-Mass Stars (Palms). Vi. Discovery of a Remarkably Red Planetary-Mass Companion to the Ab Dor Moving Group Candidate 2mass J22362452+4751425*

Bowler

Liu

Mawet

et al. 2016

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We report the discovery of an extremely red planetary-mass companion to 2MASSJ22362452+4751425, a ≈0.6M e late-K dwarf likely belonging to the ∼120 Myr AB Doradus moving group. 2M2236+4751 b was identified in multi-epoch NIRC2 adaptive optics imaging at Keck Observatory at a separation of  3. 7, or 230±20 AU in projection at the kinematic distance of 63±5pc to its host star. Assuming membership in the AB Dor group, as suggested from its kinematics, the inferred mass of 2M2236+4751 b is 11-14M Jup . Follow-up Keck/OSIRIS K-band spectroscopy of the companion reveals strong CO absorption similar to other faint red L dwarfs and lacks signs of methane absorption, despite having an effective temperature of ≈900-1200 K. With a ( J-K ) MKO color of 2.69±0.12 mag, the near-infrared slope of 2M2236+4751 b is redder than all of the HR 8799 planets and instead resembles the ≈23 Myr isolated planetary-mass object PSOJ318.5-22, implying that similarly thick photospheric clouds can persist in the atmospheres of giant planets at ages beyond 100 Myr. In near-infrared color-magnitude diagrams, 2M2236+4751 b is located at the tip of the red L dwarf sequence and appears to define the "elbow" of the AB Dor substellar isochrone separating low-gravity L dwarfs from the cooler young T dwarf track. 2M2236+4751 b is the reddest substellar companion to a star and will be a valuable benchmark to study the shared atmospheric properties of young low-mass brown dwarfs and extrasolar giant planets.

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Why Are Rapidly Rotating M Dwarfs in the Pleiades So (Infra)red? New Period Measurements Confirm Rotation-Dependent Color Offsets From the Cluster Sequence

Cited by 50 publications

References 72 publications

The SPOTS Models: A Grid of Theoretical Stellar Evolution Tracks and Isochrones for Testing the Effects of Starspots on Structure and Colors

The SPOTS Models: A Grid of Theoretical Stellar Evolution Tracks and Isochrones for Testing the Effects of Starspots on Structure and Colors

Placing the Spotted T Tauri Star LkCa 4 on an HR Diagram

Planets Around Low-Mass Stars (Palms). Vi. Discovery of a Remarkably Red Planetary-Mass Companion to the Ab Dor Moving Group Candidate 2mass J22362452+4751425*

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