Stellar flares detected with the Next Generation Transit Survey

Jackman, James A. G.; Wheatley, P. J.; Acton, Jack S.; Anderson, D. R.; Briegal, Joshua T.; Burleigh, M. R.; Casewell, Sarah L.; Gänsicke, B. T.; Gill, Samuel; Gillen, Edward; Goad, M. R.; Günther, Maximilian N.; Henderson, Beth A.; Hodgkin, S. T.; Jenkins, James S.; Pugh, Chloe E.; Queloz, D.; Raynard, Liam; Tilbrook, Rosanna H.; Watson, Christopher A.; West, R. G.

doi:10.1093/mnras/stab979

Cited by 28 publications

(37 citation statements)

References 130 publications

(186 reference statements)

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“…Guarcello et al 2019, MacGregor et al 2021, extending across spectral types (e.g. Candelaresi, Hillier, Maehara, Brandenburg, & Shibata 2014, Jackman et al 2021) and evolutionary stages (e.g. Ilin et al 2019, 2021, Goodarzi, Mehrabi, Khosroshahi, & He 2021.…”

Section: State Of the Artmentioning

confidence: 99%

Coronal Mass Ejections and Exoplanets: A Numerical Perspective

Alvarado-Gómez,

Drake,

Cohen

et al. 2021

Preprint

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Coronal mass ejections (CMEs) are more energetic than any other class of solar phenomena. They arise from the rapid release of up to 10 33 erg of magnetic energy mainly in the form of particle acceleration and bulk plasma motion. Their stellar counterparts, presumably involving much larger energies, are expected to play a fundamental role in shaping the environmental conditions around low-mass stars, in some cases perhaps with catastrophic consequences for planetary systems due to processes such as atmospheric erosion and depletion. Despite their importance, the direct observational evidence for stellar CMEs is almost non-existent. In this way, numerical simulations constitute extremely valuable tools to shed some light on eruptive behavior in the stellar regime. Here we review recent results obtained from realistic modeling of CMEs in active stars, highlighting their key role in the interpretation of currently available observational constraints. We include studies performed on M-dwarf stars, focusing on how emerging signatures in different wavelengths related to these events vary as a function of the magnetic properties of the star. Finally, the implications and relevance of these numerical results are discussed in the context of future characterization of host star-exoplanet systems.

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Section: State Of the Artmentioning

confidence: 99%

Coronal Mass Ejections and Exoplanets: A Numerical Perspective

Alvarado-Gómez,

Drake,

Cohen

et al. 2021

Preprint

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“…To ensure these MV stars had similar activity levels, their stellar rotations periods were examined. The stellar rotation period can be estimated with Lomb-Scargle periodograms 55,56 This utilises a Fourier transform to calculate the relative power of periodic signatures in a timeseries. A normalised power of 1.0 would indicate a fully periodic signal, whereas 0.0 would be a signal with no periodic nature.…”

Section: Observations With Ngtsmentioning

confidence: 99%

“…In practice, any signal 9/17 greater than 0.1 is a possible periodic signature. Periods in the range 1-30 days were searched for, using a 'frequency-grid' of 20,000 evenly spaced candidate periods (following the procedure utilised by 56 to identify periods in NGTS stellar timeseries).…”

Section: Observations With Ngtsmentioning

confidence: 99%

NGTS Observations of Enhanced Nanoflare Activity in Fully Convective Stars Linked to Plasma Resistivity

Dillon

Jess

Mathioudakis

et al. 2021

Preprint

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Previous examination of fully-convective M-dwarf stars highlighted unexplained enhanced rates of nanoflare activity. A potential explanation was linked to the helical turbulence dynamo which operates in fully convective stars. However, recent studies have found this helical dynamo does not appear significantly different to the Solar dynamo. The specific role the convective boundary plays on observed nanoflare rates, until now, was not known. Here we find evidence that fully convective M2.5V (and later) stars display greatly enhanced nanoflare rates compared with their pre-convective boundary counterparts. Importantly, the rate of nanoflare activity increases with increasing spectral sub-type, with nanoflares exhibiting greatly enhanced flaring rates via Sweet-Parker reconnection. This occurs more favourably at increased plasma resistivities experienced in these later MV stars, suggesting a direct interplay between the rate of nanoflare occurrence and the intrinsic plasma parameters. As such, nanoflare behaviour is likely to be unrelated to the behaviour of the local dynamo.

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“…Despite this predicted difference, recent work has shown that relationships between activity and rotation remain consistent from partially to fully convective stars (Wright & Drake 2016;Newton et al 2017;Wright et al 2018). Spin down is, however, believed to occur on slower timescales for fully convective stars, which accounts for the enhanced activity of mid-to-late M dwarfs (West et al 2008;Newton et al 2017;Jackman et al 2021). Therefore, rotation, activity, and the relationship between the two, are extremely useful probes of the underlying magnetic activity of ultra-cool dwarfs.…”

mentioning

confidence: 99%

“…Additionally, the recently launched Transiting Exoplanet Survey Satellite (TESS, Ricker et al (2015)) has facilitated studies of the flaring and rotating activity of cool stars (Günther et al 2020;Medina et al 2020;Seli et al 2021). Several ground-based photometric surveys, such as MEarth (Nutzman & Charbonneau 2008), the Next Generation Transit Survey (NGTS, Wheatley et al (2018)), the All-Sky Automated Survey for Supernovae (ASAS-SN, Shappee et al (2014)) and Evryscope (Law et al 2015) have also carried out detailed flare studies that include M dwarfs (West et al 2015;Mondrik et al 2018;Jackman et al 2021;Schmidt et al 2019;Martínez et al 2019;Howard et al 2019Howard et al , 2020a.…”

mentioning

confidence: 99%

A Study of Flares in the Ultra-Cool Regime from SPECULOOS-South

Murray,

Queloz,

Gillon

et al. 2022

Preprint

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We present a study of photometric flares on 154 low-mass (≤ 0.2M ) objects observed by the SPECULOOS-South Observatory from 1st June 2018 to 23rd March 2020. In this sample we identify 85 flaring objects, ranging in spectral type from M4 to L0. We detect 234 flares in this sample, with energies between 10 29.2 and 10 32.7 erg, using both automated and manual methods. With this work, we present the largest photometric sample of flares on late-M and ultra-cool dwarfs to date. By extending previous M dwarf flare studies into the ultra-cool regime, we find M5-M7 stars are more likely to flare than both earlier, and later, M dwarfs. By performing artificial flare injection-recovery tests we demonstrate that we can detect a significant proportion of flares down to an amplitude of 1 per cent, and we are most sensitive to flares on the coolest stars. Our results reveal an absence of high-energy flares on the reddest dwarfs. To probe the relations between rotation and activity for fully convective stars, we extract rotation periods for fast rotators and lower-bound period estimates of slow rotators. These rotation periods span from 2.2 hours to 65 days, and we find that the proportion of flaring stars increases for the very fastest rotators. Finally, we discuss the impact of our flare sample on planets orbiting ultra-cool stars. As stars become cooler, they flare less frequently; therefore, it is unlikely that planets around the very reddest dwarfs would enter the 'abiogenesis' zone or drive visible-light photosynthesis through flares alone.

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Stellar flares detected with the Next Generation Transit Survey

Cited by 28 publications

References 130 publications

Coronal Mass Ejections and Exoplanets: A Numerical Perspective

Coronal Mass Ejections and Exoplanets: A Numerical Perspective

NGTS Observations of Enhanced Nanoflare Activity in Fully Convective Stars Linked to Plasma Resistivity

A Study of Flares in the Ultra-Cool Regime from SPECULOOS-South

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