New constraints on the planetary system around the young active star AU Mic

Martioli, Eder; Hébrard, G.; Correia, A. C. M.; Laskar, Jacques; Étangs, A. Lecavelier des

doi:10.1051/0004-6361/202040235

Cited by 77 publications

(24 citation statements)

References 32 publications

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“…Note that DI reconstructions are performed assuming a stellar inclination of i DI = 80 paper I † To gain some space in the table, we use aliases for the references. G18, A19, W19, P20, P09, M14, paper I, Kl21 and M21 stand respectively for Gaia Collaboration et al (2018), Afram & Berdyugina (2019), White et al (2019), Plavchan et al (2020), Plavchan et al (2009), Mamajek & Bell (2014), Zicher et al (2022), Klein et al (2021) and Martioli et al (2021).…”

Section: Activity Indicatorsmentioning

confidence: 99%

“…GJ 803) is the second closest PMS star (D = 9.7248 pc;Gaia Collaboration et al 2018). This system has been intensively monitored over the past 50 years for its intense magnetic activity notably inducing ∼ 0.1-mag quasi-periodic photometric variations (e.g., Torres & Ferraz Mello 1973;Rodono et al 1986;Plavchan et al 2020;Martioli et al 2021), and frequent flaring events of variable intensity (e.g., Robinson et al 2001;Hebb et al 2007;MacGregor et al 2020;Martioli et al 2021). The detection of two transiting Neptune-sized planets from Spitzer and TESS light curves (TESS sectors 1 and 27; Plavchan et al 2020;Martioli et al 2021) has increased the already high interest of the scientific community in the system which has been intensively monitored with various state-of-the-art spectrometers since then.…”

Section: Introductionmentioning

confidence: 99%

“…This system has been intensively monitored over the past 50 years for its intense magnetic activity notably inducing ∼ 0.1-mag quasi-periodic photometric variations (e.g., Torres & Ferraz Mello 1973;Rodono et al 1986;Plavchan et al 2020;Martioli et al 2021), and frequent flaring events of variable intensity (e.g., Robinson et al 2001;Hebb et al 2007;MacGregor et al 2020;Martioli et al 2021). The detection of two transiting Neptune-sized planets from Spitzer and TESS light curves (TESS sectors 1 and 27; Plavchan et al 2020;Martioli et al 2021) has increased the already high interest of the scientific community in the system which has been intensively monitored with various state-of-the-art spectrometers since then. These follow-up observations made it possible to measure a zero-compatible spin-orbit angle (Addison et al 2020;Hirano et al 2020;Martioli et al 2020;Palle et al 2020), and a bulk density of 1.32 ± 0.2 g cm −3 for the close-in planet AU Mic b (Klein et al 2021;Cale et al 2021).…”

Section: Introductionmentioning

confidence: 99%

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One year of AU Mic with HARPS – II. Stellar activity and star–planet interaction

Klein

Zicher

Kavanagh

et al. 2022

Monthly Notices of the Royal Astronomical Society

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We present a spectroscopic analysis of a 1-year intensive monitoring campaign of the 22-Myr old planet-hosting M dwarf AU Mic using the HARPS spectrograph. In a companion paper, we reported detections of the planet radial velocity (RV) signatures of the two close-in transiting planets of the system, with respective semi-amplitudes of 5.8 ± 2.5 m s−1 and 8.5 ± 2.5 m s−1 for AU Mic b and AU Mic c. Here, we perform an independent measurement of the RV semi-amplitude of AU Mic c using Doppler imaging to simultaneously model the activity-induced distortions and the planet-induced shifts in the line profiles. The resulting semi-amplitude of 13.3 ± 4.1 m s−1 for AU Mic c reinforces the idea that the planet features a surprisingly large inner density, in tension with current standard models of core accretion. Our brightness maps feature significantly higher spot coverage and lower level of differential rotation than the brightness maps obtained in late 2019 with the SPIRou spectropolarimeter, suggesting that the stellar magnetic activity has evolved dramatically over a ∼1-yr time span. Additionally, we report a 3-σ detection of a modulation at 8.33 ± 0.04 d of the He I D3 (5875.62 Å) emission flux, close to the 8.46-d orbital period of AU Mic b. The power of this emission (a few 1017 W) is consistent with 3D magnetohydrodynamical simulations of the interaction between stellar wind and the close-in planet if the latter hosts a magnetic field of ∼10 G. Spectropolarimetric observations of the star are needed to firmly elucidate the origin of the observed chromospheric variability.

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Section: Activity Indicatorsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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One year of AU Mic with HARPS – II. Stellar activity and star–planet interaction

Klein

Zicher

Kavanagh

et al. 2022

Monthly Notices of the Royal Astronomical Society

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“…Optical and far-IR imaging also revealed the presence of an extended halo surrounding the disk (Matthews et al 2015). The system is also thought to host two close-in, Neptune-sized planets as suggested by TESS light curves (Plavchan et al 2020;Martioli et al 2021).…”

Section: Application To Au Micmentioning

confidence: 90%

Rave: A non-parametric method for recovering the surface brightness and height profiles of edge-on debris disks

Han,

Wyatt,

Matra

2022

Preprint

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Extrasolar analogues of the Solar System's Kuiper belt offer unique constraints on outer planetary system architecture. Radial features such as the sharpness of disk edges and substructures such as gaps may be indicative of embedded planets within a disk. Vertically, the height of a disk can constrain the mass of embedded bodies. Edge-on debris disks offer a unique opportunity to simultaneously access the radial and vertical distribution of material, however recovering either distribution in an unbiased way is challenging. In this study, we present a non-parametric method to recover the surface brightness profile (face-on surface brightness as a function of radius) and height profile (scale height as a function of radius) of azimuthally symmetric, edge-on debris disks. The method is primarily designed for observations at thermal emission wavelengths, but is also applicable to scattered light observations under the assumption of isotropic scattering. By removing assumptions on underlying functional forms, this algorithm provides more realistic constraints on disk structures. We also apply this technique to ALMA observations of the AU Mic debris disk and derive a surface brightness profile consistent with estimates from parametric approaches, but with a more realistic range of possible models that is independent of parametrisation assumptions. Our results are consistent with a uniform scale height of 0.8 au, but a scale height that increases linearly with radius is also possible.

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“…Recently, AU Mic, an M0-M1 (Pecaut & Mamajek 2013;Gaidos et al 2014) pre-main sequence dwarf star, and a member of the β Pic young moving group, which is 16 − 29 Myr old (Malo et al 2014;Binks & Jeffries 2014;Mamajek & Bell 2014;Bell et al 2015;Binks & Jeffries 2016;Shkolnik et al 2017;Miret-Roig et al 2020), was discovered to be a favorable candidate for magnetic star-planet interactions (Kavanagh et al 2021). The system hosts two planets in close orbits near a 2:1 mean-motion resonance, AU Mic b and AU Mic c (Plavchan et al 2020;Martioli et al 2021), with masses M b = 11.7 ± 5.0M ⊕ and M c = 22.2 ± 6.7M ⊕ (Zicher et al 2022). Several papers reported system parameters of AU Mic based on photometry from the Transiting Exoplanet Survey Satellite (TESS, Ricker et al 2014), the CHEOPS mission (Benz et al 2021), and HARPS (Mayor et al 2003) spectroscopy (Plavchan et al 2020;Cale et al 2021;Gilbert et al 2022;Zicher et al 2022), which are mutually compatible within uncertainties.…”

Section: Introductionmentioning

confidence: 99%

Searching for flaring star-planet interactions in AU Mic TESS observations

Ilin,

Poppenhäger

2022

Preprint

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Planets that closely orbit magnetically active stars are thought to be able to interact with their magnetic fields in a way that modulates stellar activity. This modulation in phase with the planetary orbit, such as enhanced X-ray activity, chromospheric spots, radio emission, or flares, is considered the clearest sign of magnetic star-planet interaction (SPI). However, the magnitude of this interaction is poorly constrained, and the intermittent nature of the interaction is a challenge for observers. AU Mic is an early M dwarf, and the most actively flaring planet host detected to date. Its innermost companion, AU Mic b, is a promising target for magnetic SPI observations. We used optical light curves of AU Mic obtained by the Transiting Exoplanet Survey Satellite to search for signs of flaring SPI with AU Mic b using a customized Anderson-Darling test. In the about 50 days of observations, the flare distributions with orbital, rotational, and synodic periods were generally consistent with intrinsic stellar flaring. We found the strongest deviation (p = 0.07, n = 71) from intrinsic flaring with the orbital period of AU Mic b, in the high energy half of our sample (ED > 1 s). If it reflects the true SPI signal from AU Mic b, extending the observing time by a factor of 2 − 3 will yield a > 3σ detection. Continued monitoring of AU Mic may therefore reveal flaring SPI with orbital phase, while rotational modulation will smear out due to the star's strong differential rotation.

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New constraints on the planetary system around the young active star AU Mic

Cited by 77 publications

References 32 publications

One year of AU Mic with HARPS – II. Stellar activity and star–planet interaction

One year of AU Mic with HARPS – II. Stellar activity and star–planet interaction

Rave: A non-parametric method for recovering the surface brightness and height profiles of edge-on debris disks

Searching for flaring star-planet interactions in AU Mic TESS observations

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