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Stellar flares

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arxiv 2402.07885 v1 pith:2XVU7QE2 submitted 2024-02-12 astro-ph.SR

Stellar flares

classification astro-ph.SR
keywords stellarflaresflarestarscomparisonevolutiongreaterlast
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Magnetic storms on stars manifest as remarkable, randomly occurring changes of the luminosity over durations that are tiny in comparison to the normal evolution of stars. These stellar flares are bursts of electromagnetic radiation from X-ray to radio wavelengths, and they occur on most stars with outer convection zones. They are analogous to the events on the Sun known as solar flares, which impact our everyday life and modern technological society. Stellar flares, however, can attain much greater energies than those on the Sun. Despite this, we think that these phenomena are rather similar in origin to solar flares, which result from a catastrophic conversion of latent magnetic field energy into atmospheric heating within a region that is relatively small in comparison to normal stellar sizes. We review the last several decades of stellar flare research. We summarize multi-wavelength observational results and the associated thermal and nonthermal processes in flaring stellar atmospheres. Static and hydrodynamic models are reviewed with an emphasis on recent progress in radiation-hydrodynamics and the physical diagnostics in flare spectra. Thanks to their effects on the space weather of exoplanetary systems (and thus in our search for life elsewhere in the universe) and their preponderance in \emph{Kepler} mission data, white-light stellar flares have re-emerged in the last decade as a widely-impactful area of study within astrophysics. Yet, there is still much we do not understand, both empirically and theoretically, about the spectrum of flare radiation, its origin, and its time evolution. We conclude with several big-picture questions that are fundamental in our pursuit toward a greater understanding of these enigmatic stellar phonemena and, by extension, those on the Sun.

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Cited by 1 Pith paper

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  1. Probing Flare-Associated Eruptions on AB Doradus via X-ray Absorption Variations

    astro-ph.SR 2026-07 conditional novelty 4.5

    Complex overlapping X-ray flares on AB Dor show phase-locked NH enhancements interpreted as transient cool absorbing plasma from eruptive coronal restructuring, while classical flares do not.