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Main Authors: Washinoue, Haruka, Takasao, Shinsuke, Furuya, Kenji
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.04946
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author Washinoue, Haruka
Takasao, Shinsuke
Furuya, Kenji
author_facet Washinoue, Haruka
Takasao, Shinsuke
Furuya, Kenji
contents X-rays have significant impacts on cold, weakly ionized protoplanetary disks by increasing the ionization rate and driving chemical reactions. Stellar flares are explosions that emit intense X-rays and are the unique source of hard X-rays with an energy of $\gtrsim10$ keV in the protoplanetary disk systems. Hard X-rays should be carefully taken into account in models as they can reach the disk midplane as a result of scattering in the disk atmospheres. However, previous models are insufficient to predict the hard X-ray spectra because of simplifications in flare models. We develop a model of X-ray spectra of stellar flares based on observations and flare theories. The flare temperature and nonthermal electron emissions are modeled as functions of flare energy, which allows us to better predict the hard X-ray photon flux than before. Using our X-ray model, we conduct radiative transfer calculations to investigate the impact of flare hard X-rays on disk ionization, with a particular focus on the protoplanetary disk around a T Tauri star. We demonstrate that for a flare with an energy of $ 10^{35}$ erg, X-ray photons with $\gtrsim 5$ keV increase the ionization rates more than galactic cosmic rays down to $z \approx 0.1R$. The contribution of flare X-rays to the ionization at the midplane depends on the disk parameters such as disk mass and dust settling. We also find that the 10-year-averaged X-rays from multiple flares could certainly contribute to the ionization. These results emphasize the importance of stellar flares on the disk evolution.
format Preprint
id arxiv_https___arxiv_org_abs_2406_04946
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Effect of time-varying X-ray emission from stellar flares on the ionization of protoplanetary disks
Washinoue, Haruka
Takasao, Shinsuke
Furuya, Kenji
Solar and Stellar Astrophysics
Earth and Planetary Astrophysics
High Energy Astrophysical Phenomena
X-rays have significant impacts on cold, weakly ionized protoplanetary disks by increasing the ionization rate and driving chemical reactions. Stellar flares are explosions that emit intense X-rays and are the unique source of hard X-rays with an energy of $\gtrsim10$ keV in the protoplanetary disk systems. Hard X-rays should be carefully taken into account in models as they can reach the disk midplane as a result of scattering in the disk atmospheres. However, previous models are insufficient to predict the hard X-ray spectra because of simplifications in flare models. We develop a model of X-ray spectra of stellar flares based on observations and flare theories. The flare temperature and nonthermal electron emissions are modeled as functions of flare energy, which allows us to better predict the hard X-ray photon flux than before. Using our X-ray model, we conduct radiative transfer calculations to investigate the impact of flare hard X-rays on disk ionization, with a particular focus on the protoplanetary disk around a T Tauri star. We demonstrate that for a flare with an energy of $ 10^{35}$ erg, X-ray photons with $\gtrsim 5$ keV increase the ionization rates more than galactic cosmic rays down to $z \approx 0.1R$. The contribution of flare X-rays to the ionization at the midplane depends on the disk parameters such as disk mass and dust settling. We also find that the 10-year-averaged X-rays from multiple flares could certainly contribute to the ionization. These results emphasize the importance of stellar flares on the disk evolution.
title Effect of time-varying X-ray emission from stellar flares on the ionization of protoplanetary disks
topic Solar and Stellar Astrophysics
Earth and Planetary Astrophysics
High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2406.04946