<i>K2</i> Ultracool Dwarfs Survey – VI. White light superflares observed on an L5 dwarf and flare rates of L dwarfs

Paudel, Rishi R.; Gizis, John E.; Mullan, D. J.; Schmidt, Sarah J.; Burgasser, Adam J.; Williams, Peter K. G.

doi:10.1093/mnras/staa1137

Cited by 20 publications

(12 citation statements)

References 71 publications

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“…The differentiation seen as a function of mass is not inconsistent with the similar flare properties seen across a large range of stellar masses (e.g. De Luca et al 2020;Paudel et al 2020). Rather, higher-energy flares occur more frequently on more massive M-dwarfs prior to spindown (e.g.…”

Section: Flare Energetics and Morphology Predict Temperaturesupporting

confidence: 49%

EvryFlare III: Temperature Evolution and Habitability Impacts of Dozens of Superflares Observed Simultaneously by Evryscope and TESS

Howard,

Corbett,

Law

et al. 2020

Preprint

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Superflares may provide the dominant source of biologically-relevant UV radiation to rocky habitablezone M-dwarf planets (M-Earths), altering planetary atmospheres and conditions for surface life. The combined line and continuum flare emission has usually been approximated by a 9000 K blackbody. If superflares are hotter, then the UV emission may be 10× higher than predicted from the optical. However, it is unknown for how long M-dwarf superflares reach temperatures above 9000 K. Only a handful of M-dwarf superflares have been recorded with multi-wavelength high-cadence observations. We double the total number of events in the literature using simultaneous Evryscope and TESS observations to provide the first systematic exploration of the temperature evolution of M-dwarf superflares. We also increase the number of superflaring M-dwarfs with published time-resolved blackbody evolution by ∼10×. We measure temperatures at 2 min cadence for 42 superflares from 27 K5-M5 dwarfs. We find superflare peak temperatures (defined as the mean of temperatures corresponding to flare FWHM) increase with flare energy and impulse. We find the amount of time flares emit at temperatures above 14,000 K depends on energy. We discover 43% of the flares emit above 14,000 K, 23% emit above 20,000 K and 5% emit above 30,000 K. The largest and hottest flare briefly reached 42,000 K. Some do not reach 14,000 K. During superflares, we estimate M-Earths orbiting <200 Myr stars typically receive a top-of-atmosphere UV-C flux of ∼120 W m −2 and up to 10 3 W m −2 , 100-1000× the time-averaged XUV flux from Proxima Cen.

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Section: Flare Energetics and Morphology Predict Temperaturesupporting

confidence: 49%

EvryFlare III: Temperature Evolution and Habitability Impacts of Dozens of Superflares Observed Simultaneously by Evryscope and TESS

Howard,

Corbett,

Law

et al. 2020

Preprint

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“…For low-mass main sequence stars, spectral classes K and M, flare stars are common, also powered by magnetic reconnection. Superflares (as greatly more energetic than normal flares) also occur on ordinary very-low mass main sequence stars, for example on Proxima Centauri (Howard et al 2018), L-type dwarfs (Paudel et al 2020), plus two late-M stars with Superflare amplitudes 9.5-16 mag (Schaefer 1990). For G-type main sequence stars, Superflares are seen with energies up to 2×10 38 ergs in field stars (Schaefer et al 2000), and are very-well observed on many solarlike stars inside the Kelper field (Maehara et al 2012).…”

Section: The Nature Of the Superflaresmentioning

confidence: 99%

Discovery of Extreme, Roughly-Daily Superflares on the Recurrent Nova V2487 Oph

Schaefer,

Pagnotta,

Zoppelt

2022

Preprint

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V2487 Oph is a recurrent nova with detected eruptions in 1900 and 1998. Startlingly, V2487 Oph shows flares, called 'Superflares', with up to 1.10 mag amplitude, fast rises of under one-minute, always with an initial impulsive spike followed by a roughly-exponential tail, typically one-hour durations, and with random event times averaging once-per-day. The typical flare energy 𝐸 is over 10 38 ergs, while the yearly energy budget is 10 41 ergs. V2487 Oph Superflares obey three relations; the number distribution of flare energies scales as 𝐸 −2.34±0.35 , the waiting time from one flare to the next is proportional to 𝐸 of the first event, and flare durations scale as 𝐸 0.44±0.03 . Scenarios involving gravitational energy and nuclear energy fail to satisfy the three relations. The magnetic energy scenario, however, can explain all three relations. This scenario has magnetic field lines above the disc being twisted and amplified by the motions of their footprints, with magnetic reconnection releasing energy that comes out as Superflare light. This exact mechanism is already well known to occur in white light solar flares, in ordinary M-type flare stars, and in the many Superflare stars observed all across the H-R diagram. Superflares on Superflare stars have rise times, light curve shapes and durations that are very similar to those on V2487 Oph. So we conclude that the V2487 Oph Superflares are caused by large-scale magnetic reconnection. V2487 Oph is now the most extreme Superflare star, exhibiting the largest known flare energy (1.6×10 39 ergs) and the fastest occurrence rate.

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“…To estimate the false discovery rate (FDR), some studies (Kowalski et al 2009;Osten et al 2012;Paudel et al 2018Paudel et al , 2020 have applied the FDR analysis following Miller et al (2001). However, the Miller's method is not applied to our project, because it requires a large number of null samples manually selected from the dataset of light curves, but this work cannot be finished automatically in real time by our pipeline.…”

Section: Flare Searchmentioning

confidence: 99%

Minute-cadence Observations of the LAMOST Fields with the TMTS: I. Methodology of Detecting Short-period Variables and Results from the first-year Survey

Lin,

Wang,

et al. 2021

Preprint

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Tsinghua University-Ma Huateng Telescopes for Survey (TMTS), located at Xinglong Station of NAOC, has a field of view up to 18 deg 2 . The TMTS has started to monitor the LAMOST sky areas since 2020, with the uninterrupted observations lasting for about 6 hours on average for each sky area and a cadence of about 1 minute. Here we introduce the data analysis and preliminary scientific results for the first-year observations, which covered 188 LAMOST plates (≈ 1970 deg 2 ). These observations have generated over 4.9 million uninterrupted light curves, with at least 100 epochs for each of them. These light curves correspond to 4.26 million Gaia-DR2 sources, among which 285 thousand sources are found to have multi-epoch spectra from the LAMOST. By analysing these light curves with the Lomb-Scargle periodograms, we identify more than 3700 periodic variable star candidates with periods below ≈ 7.5 hours, primarily consisting of eclipsing binaries and 𝛿 Scuti stars. Those short-period binaries will provide important constraints on theories of binary evolution and possible sources for space gravitational wave experiments in the future. Moreover, we also identified 42 flare stars by searching rapidly-evolving signals in the light curves. The densely-sampled light curves from the TMTS allow us to better quantify the shapes and durations for these flares.

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K2 Ultracool Dwarfs Survey – VI. White light superflares observed on an L5 dwarf and flare rates of L dwarfs

Cited by 20 publications

References 71 publications

EvryFlare III: Temperature Evolution and Habitability Impacts of Dozens of Superflares Observed Simultaneously by Evryscope and TESS

EvryFlare III: Temperature Evolution and Habitability Impacts of Dozens of Superflares Observed Simultaneously by Evryscope and TESS

Discovery of Extreme, Roughly-Daily Superflares on the Recurrent Nova V2487 Oph

Minute-cadence Observations of the LAMOST Fields with the TMTS: I. Methodology of Detecting Short-period Variables and Results from the first-year Survey

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