Stellar Energetic Particle Transport in the Turbulent and CME-disrupted Stellar Wind of AU~Microscopii

Fraschetti, F.; Alvarado‐Gómez, Julián D.; Drake, J. J.; CoheN, O.; Garraffo, C.

doi:10.48550/arxiv.2207.08952

Cited by 1 publication

(2 citation statements)

References 79 publications

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“…On the other hand, previous stellar wind simulations including CMEs (Alvarado-Gómez et al 2018) have suggested that strong solar-like CMEs may be suppressed by a largescale dipole stellar magnetic field of 75 G which would affect the corresponding stellar energetic particle fluxes. Fraschetti et al (2022) showed for the AU Mic system how the stellar energetic particle flux distribution reaching the planetary orbits is strongly altered by the passage of a CME. To complicate matters further, solar CME-CME interactions account for more than 25% of the major geomagnetic storms observed (Zhang et al 2007).…”

Section: Maximum Stellar Energetic Particle Momentummentioning

confidence: 99%

“…We relate the maximum energy of the stellar energetic particles accelerated by stellar flares to stellar magnetic field strength, following Rodgers-Lee et al (2021a), and show how this can be related to stellar X-ray luminosity. Previous studies have investigated the distribution of stellar energetic particles in the Trappist-1 and AU Mic systems (Fraschetti et al 2019(Fraschetti et al , 2022. In the latter case, following a perturbation of the interplanetary medium by a coronal mass ejection (CME).…”

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confidence: 99%

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The energetic particle environment of a GJ 436 b-like planet

Rodgers-Lee

Rimmer

Vidotto

et al. 2023

Monthly Notices of the Royal Astronomical Society

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A key first step to constrain the impact of energetic particles in exoplanet atmospheres is to detect the chemical signature of ionisation due to stellar energetic particles and Galactic cosmic rays. We focus on GJ 436, a well-studied M dwarf with a warm Neptune-like exoplanet. We demonstrate how the maximum stellar energetic particle momentum can be estimated from the stellar X-ray luminosity. We model energetic particle transport through the atmosphere of a hypothetical exoplanet at orbital distances between a = 0.01 − 0.2au from GJ 436, including GJ 436 b’s orbital distance (0.028 au). For these distances we find that, at top-of-atmosphere, stellar energetic particles ionise molecular hydrogen at a rate of $\zeta _{\rm StEP,H_2} \sim 4\times 10^{-10}-2\times 10^{-13} \mathrm{s^{-1}}$. In comparison, Galactic cosmic rays alone lead to $\zeta _{\rm GCR, H_2}\sim 2\times 10^{-20}-10^{-18} \mathrm{s^{-1}}$. At 10au we find that ionisation due to Galactic cosmic rays equals that of stellar energetic particles: $\zeta _{\rm GCR,H_2} = \zeta _{\rm StEP,H_2} \sim 7\times 10^{-18} \rm {s^{-1}}$ for the top-of-atmosphere ionisation rate. At GJ 436 b’s orbital distance, the maximum ion-pair production rate due to stellar energetic particles occurs at pressure P ∼ 10−3bar while Galactic cosmic rays dominate for P > 102 bar. These high pressures are similar to what is expected for a post-impact early Earth atmosphere. The results presented here will be used to quantify the chemical signatures of energetic particles in warm Neptune-like atmospheres.

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Section: Maximum Stellar Energetic Particle Momentummentioning

confidence: 99%

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confidence: 99%