Stellar Superflares Observed Simultaneously with Kepler and XMM-Newton

Solar and stellar flares are powerful events that produce intense radiation across the electromagnetic spectrum. Multiwavelength observations are highly important for understanding the nature of flares, because different flare-related processes reveal themselves in different spectral ranges. To stud...

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Bibliographic Details
Published in:The Astrophysical journal 2021-05, Vol.912 (1), p.81
Main Authors: Kuznetsov, Alexey A., Kolotkov, Dmitrii Y.
Format: Article
Language:English
Subjects:
Astrophysics
Emission
Magnetic fields
Magnetic reconnection
Markov chain Monte Carlo
Optical counterparts (astronomy)
Optical flares
Optical observations
Radiation
Scaling laws
Soft x rays
Solar flares
Solar power
Spectral classification
Stellar flares
Stellar magnetic fields
Stellar x-ray flares
X ray spectra
X-ray astronomy
X-ray emissions
X-rays
XMM (spacecraft)
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Summary:Solar and stellar flares are powerful events that produce intense radiation across the electromagnetic spectrum. Multiwavelength observations are highly important for understanding the nature of flares, because different flare-related processes reveal themselves in different spectral ranges. To study the correlation between thermal and nonthermal processes in stellar flares, we have searched the databases of Kepler (optical observations) and XMM-Newton (soft X-rays) for the flares observed simultaneously with both instruments; nine distinctive flares (with energies exceeding 10 33 erg) on three stars (of K-M spectral classes) have been found. We have analyzed and compared the flare parameters in the optical and X-ray spectral ranges; we have also compared the obtained results with similar observations of solar flares. Most of the studied stellar flares released more energy in the optical range than in X-rays. In one flare, X-ray emission strongly dominated, which could be caused either by a soft spectrum of energetic electrons or by a near-limb position of this flare. The X-ray flares were typically delayed with respect to and shorter than their optical counterparts, which is partially consistent with the Neupert effect. Using the scaling laws based on the magnetic reconnection theory, we have estimated the characteristic magnetic field strengths in the stellar active regions and the sizes of these active regions as about 25–70 G and 250,000–500,000 km, respectively. The observed stellar superflares appear to be scaled-up versions of solar flares, with a similar underlying mechanism and nearly the same characteristic magnetic field values, but with much larger active region sizes.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/abf569