λ And: a post-main-sequence wind from a solar-mass star

Fionnagáin, Dúalta Ó; Vidotto, A. A.; Petit, P.; Neiner, C.; Manchester, W.; Folsom, C. P.; Hallinan, Gregg

doi:10.1093/mnras/staa3468

Cited by 21 publications

(12 citation statements)

References 114 publications

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“…This is caused by the funnelling geometry of the magnetic field which assists in the driving of escape in the polar flows, compared to the predominantly night-side outflow in the 0G model. This is similar to what is seen in stellar wind models with magnetic fields (Vidotto et al 2009(Vidotto et al , 2014Réville et al 2015;Ó Fionnagáin et al 2019Ó Fionnagáin et al , 2021Kavanagh et al 2019Kavanagh et al , 2021. However for stronger field strengths (>3G) the magnetic field does not cause significant changes to the escape rate, though it does change the observational signatures of this escape, as discussed in section 4.…”

Section: Effect Of Magnetic Fields: Atmospheric Escapesupporting

confidence: 85%

The effects of magnetic fields on observational signatures of atmospheric escape in exoplanets: Double tail structures

Vidotto

Hazra

D’Angelo

et al. 2021

Monthly Notices of the Royal Astronomical Society

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Using 3D radiative MHD simulations and Lyman-α transit calculations, we investigate the effect of magnetic fields on the observational signatures of atmospheric escape in exoplanets. Using the same stellar wind, we vary the planet’s dipole field strength (Bp) from 0 to 10G. For Bp < 3G, the structure of the escaping atmosphere begins to break away from a comet-like tail following the planet (Bp = 0), as we see more absorbing material above and below the orbital plane. For Bp ≥ 3G, we find a “dead-zone” around the equator, where low velocity material is trapped in the closed magnetic field lines. The dead-zone separates two polar outflows where absorbing material escapes along open field lines, leading to a double tail structure, above and below the orbital plane. We demonstrate that atmospheric escape in magnetised planets occurs through polar outflows, as opposed to the predominantly night-side escape in non-magnetised models. We find a small increase in escape rate with Bp, though this should not affect the timescale of atmospheric loss. As the size of the dead-zone increases with Bp, so does the line centre absorption in Lyman-α, as more low-velocity neutral hydrogen covers the stellar disc during transit. For Bp < 3G the absorption in the blue wing decreases, as the escaping atmosphere is less funnelled along the line of sight by the stellar wind. In the red wing (and for Bp > 3G in the blue wing) the absorption increases caused by the growing volume of the magnetosphere. Finally we show that transits below and above the mid-disc differ caused by the asymmetry of the double tail structure.

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Section: Effect Of Magnetic Fields: Atmospheric Escapesupporting

confidence: 85%

The effects of magnetic fields on observational signatures of atmospheric escape in exoplanets: Double tail structures

Vidotto

Hazra

D’Angelo

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…In the case of the Sun, multiple solar observatories produce high-resolution synoptic magnetograms which can be used as an input (Riley et al 2014). Stellar wind models use low-resolution magnetic maps of stars as input (Vidotto et al 2011(Vidotto et al , 2014Nicholson et al 2016;Alvarado-Gómez et al 2016a,b;Garraffo et al 2013Garraffo et al , 2015Garraffo et al , 2016Fionnagáin et al 2019), which are reconstructed using the technique of Zeeman Doppler imaging (ZDI;Semel 1989). This imagining technique reconstructs the large-scale field using spectropolarimetric observations, where the field is typically described using spherical harmonic expansion.…”

Section: Introductionmentioning

confidence: 99%

The solar wind from a stellar perspective

Saikia

Jin

Johnstone

et al. 2020

A&A

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Context. Due to the effects that they can have on the atmospheres of exoplanets, stellar winds have recently received significant attention in the literature. Alfvén-wave-driven 3D magnetohydrodynamic models, which are increasingly used to predict stellar wind properties, contain unconstrained parameters and rely on low-resolution stellar magnetograms. Aims. In this paper, we explore the effects of the input Alfvén wave energy flux and the surface magnetogram on the wind properties predicted by the Alfvén Wave Solar Model (AWSoM) model for both the solar and stellar winds. Methods. We lowered the resolution of two solar magnetograms during solar cycle maximum and minimum using spherical harmonic decomposition. The Alfvén wave energy was altered based on non-thermal velocities determined from a far ultraviolet spectrum of the solar twin 18 Sco. Additionally, low-resolution magnetograms of three solar analogues, 18 Sco, HD 76151, and HN Peg, were obtained using Zeeman Doppler imaging and used as a proxy for the solar magnetogram. Finally, the simulated wind properties were compared to Advanced Composition Explorer (ACE) observations. Results. AWSoM simulations using well constrained input parameters taken from solar observations can reproduce the observed solar wind mass loss and angular momentum loss rates. The simulated wind velocity, proton density, and ram pressure differ from ACE observations by a factor of approximately two. The resolution of the magnetogram has a small impact on the wind properties and only during cycle maximum. However, variation in Alfvén wave energy influences the wind properties irrespective of the solar cycle activity level. Furthermore, solar wind simulations carried out using the low-resolution magnetogram of the three stars instead of the solar magnetogram could lead to an order of a magnitude difference in the simulated solar wind properties. Conclusions. The choice in Alfvén energy has a stronger influence on the wind output compared to the magnetogram resolution. The influence could be even stronger for stars whose input boundary conditions are not as well constrained as those of the Sun. Unsurprisingly, replacing the solar magnetogram with a stellar magnetogram could lead to completely inaccurate solar wind properties, and should be avoided in solar and stellar wind simulations. Further observational and theoretical work is needed to fully understand the complexity of solar and stellar winds.

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“…There appears to be growing (Garraffo et al 2016;Dong et al 2018;Airapetian et al 2021;Kavanagh et al 2021;Ó Fionnagáin et al 2021) interest in scaling the Poynting flux-to-field ratio Π {𝐵; variations in this parameter affect the steady-state wind mass loss as 9…”

Section: Discussionmentioning

confidence: 99%

The winds of young Solar-type stars in Coma Berenices and Hercules-Lyra

Evensberget,

Carter,

Marsden

et al. 2021

Preprint

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We present wind models of ten young Solar-type stars in the Hercules-Lyra association and the Coma Berenices cluster aged around "0.26 Gyr and "0.58 Gyr respectively. Combined with five previously modelled stars in the Hyades cluster, aged "0.63 Gyr, we obtain a large atlas of fifteen observationally based wind models. We find varied geometries, multi-armed structures in the equatorial plane, and a greater spread in quantities such as the angular momentum loss. In our models we infer variation of a factor of "6 in wind angular momentum loss 9 𝐽 and a factor of "2 in wind mass loss 9 𝑀 based on magnetic field geometry differences when adjusting for the unsigned surface magnetic flux. We observe a large variation factor of "4 in wind pressure for an Earth-like planet; we attribute this to variations in the 'magnetic inclination' of the magnetic dipole axis with respect to the stellar axis of rotation. Within our models, we observe a tight correlation between unsigned open magnetic flux and angular momentum loss. To account for possible underreporting of the observed magnetic field strength we investigate a second series of wind models where the magnetic field has been scaled by a factor of 5. This gives 9 𝑀 9 𝐵 0.4 and 9 𝐽 9 𝐵 1.0 as a result of pure magnetic scaling.

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λ And: a post-main-sequence wind from a solar-mass star

Cited by 21 publications

References 114 publications

The effects of magnetic fields on observational signatures of atmospheric escape in exoplanets: Double tail structures

The effects of magnetic fields on observational signatures of atmospheric escape in exoplanets: Double tail structures

The solar wind from a stellar perspective

The winds of young Solar-type stars in Coma Berenices and Hercules-Lyra

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