Magnetic Activity of F-, G-, and K-type Stars in the LAMOST–Kepler Field

Zhang, Jinghua; Bi, Shaolan; Li, Yaguang; Jiang, Jingyang; Li, Tanda; He, Hongliang; Jiang, Yu; Khanna, Shourya; Ge, Zhishuai; Liu, Kang; Tian, Zhijia; Wu, Yaqian; Zhang, Xianfei

doi:10.3847/1538-4365/ab6165

Cited by 40 publications

(41 citation statements)

References 128 publications

(205 reference statements)

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“…This emission is spatially extended and well modeled by thermal bremsstrahlung emission arising from thermal plasma in the accretion flow around the Bondi radius (Quataert 2002;Baganoff et al 2003;Yuan et al 2003;Liu et al 2004;Xu et al 2006;Wang et al 2013). This quiescent behaviour is punctuated by X-ray flares of luminosities varying from ∼ 10s to 100s of times quiescence (or 100s to 1000s of times their locally-emitted background since the inner accretion flow contributes 10% of the quiescent emission; Baganoff et al 2001;Goldwurm et al 2003;Porquet et al 2003Porquet et al , 2008Belanger et al 2005;Nowak et al 2012;Neilsen et al 2013Neilsen et al , 2015Degenaar et al 2013;Barriere et al 2014;Ponti et al 2015;Mossoux et al 2016;Yuan & Wang 2016;Zhang et al 2017;Yuan et al 2018;Boyce et al 2019;Haggard et al 2019).…”

Section: Introductionmentioning

confidence: 86%

“…Possible sources of flares include magnetic reconnection, stochastic acceleration, shocks from jets or the accretion flow, or even tidal disruption of asteroids (Markoff et al 2001;Liu & Melia 2002;Yuan et al 2003;Liu et al 2004;Čadež et al 2008;Kostić et al 2009;Zubovas et al 2012;Dibi et al 2014Dibi et al , 2016Ball et al 2016Ball et al , 2018 whereas the responsible radiation mechanisms are likely synchrotron or synchrotron self-Compton in nature (Marrone et al 2008;Dodds-Eden et al 2009;Eckart et al 2009;Witzel et al 2012;Nowak et al 2012;Barriere et al 2014;Neilsen et al 2015;Ponti et al 2017;Zhang et al 2017) but not inverse-Compton where the photons that get up-scattered to X-rays come from an external region (Boyce et al 2019). Flares share a consistent spectrum with a photon index Γ ∼ 2 (Nowak et al 2012;Neilsen et al 2013;Ponti et al 2017;Yuan et al 2018) and their timescale of minutes to hours points to an origin at ∼ 10's of Schwarzschild radii Quataert 2003).…”

Section: Introductionmentioning

confidence: 99%

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No Sign of G2's Encounter Affecting Sgr A*'s X-Ray Flaring Rate from Chandra Observations

Bouffard

Haggard

Nowak

et al. 2019

ApJ

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An unusual object, G2, had its pericenter passage around Sgr A*, the 4 × 10 6 M supermassive black hole in the Galactic Centre, in Summer 2014. Several research teams have reported evidence that following G2's pericenter encounter the rate of Sgr A*'s bright X-ray flares increased significantly. Our analysis carefully treats varying flux contamination from a nearby magnetic neutron star and is free from complications induced by using data from multiple X-ray observatories with different spatial resolutions. We test the scenario of an increased bright X-ray flaring rate using a massive dataset from the Chandra X-ray Observatory, the only X-ray instrument that can spatially distinguish between Sgr A* and the nearby Galactic Centre magnetar throughout the full extended period encompassing G2's encounter with Sgr A*. We use X-ray data from the 3 Ms observations of the Chandra X-ray Visionary Program (XVP) in 2012 as well as an additional 1.5 Ms of observations up to 2018. We use detected flares to make distributions of flare properties. Using simulations of X-ray flares accounting for important factors such as the different Chandra instrument modes, we test the null hypothesis on Sgr A*'s bright (or any flare category) X-ray flaring rate around different potential change points. In contrast to previous studies, our results are consistent with the null hypothesis; the same model parameters produce distributions consistent with the observed ones around any plausible change point.

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Section: Introductionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

No Sign of G2's Encounter Affecting Sgr A*'s X-Ray Flaring Rate from Chandra Observations

Bouffard

Haggard

Nowak

et al. 2019

ApJ

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“…& Egeland 2019;van Saders et al 2019); and lastly, the importance of all of the above in regards to the deep connection between rotation and the various aspects of stellar activity (e.g., coronal X-ray and chromospheric Ca ii and Hα emission, UV excess, flares;Stelzer et al 2013;Zhang et al 2020;Dixon et al 2020;Ilin et al 2020; Godoy-Rivera et al 2020, submitted), and its dependence on stellar structure, the presence of a tachocline, and the evolutionary phase (e.g.,Wright et al 2018;Lehtinen et al 2020). …”

mentioning

confidence: 99%

Stellar Rotation in the Gaia Era: Revised Open Clusters’ Sequences

Godoy-Rivera

Pinsonneault

Rebull

2021

ApJS

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The period versus mass diagrams (i.e., rotational sequences) of open clusters provide crucial constraints for angular momentum evolution studies. However, their memberships are often heavily contaminated by field stars, which could potentially bias the interpretations. In this paper, we use data from Gaia DR2 to reassess the memberships of seven open clusters with ground- and space-based rotational data, and present an updated view of stellar rotation as a function of mass and age. We use the Gaia astrometry to identify the cluster members in phase space, and the photometry to derive revised ages and place the stars on a consistent mass scale. Applying our membership analysis to the rotational sequences reveals that: (1) the contamination in clusters observed from the ground can reach up to ∼35%; (2) the overall fraction of rotational outliers decreases substantially when the field contaminants are removed, but some outliers persist; (3) there is a sharp upper edge in the rotation periods at young ages; (4) at young ages, stars in the 1.0–0.6M ⊙ range inhabit a global maximum of rotation periods, potentially providing an optimal window for habitable planets. Additionally, we see clear evidence for a strongly mass-dependent spin-down process. In the regime where rapid rotators are leaving the saturated domain, the rotational distributions broaden (in contradiction with popular models), which we interpret as evidence that the torque must be lower for rapid rotators than for intermediate ones. The cleaned rotational sequences from ground-based observations can be as constraining as those obtained from space.

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“…对恒星磁活动和恒星爆发的研究目前已成为一个热点研究领域, 包括恒星磁场演化 [71,72,73,74,75] 、恒星耀斑 [76,77,78,79,80] 和星冕物质抛射 [81,82,83,84] [68,85] ), 可观测的恒星耀斑的能量范围在 10 32 -10 38 erg [86] ,因而可称之为"超级耀斑". 近年来随着 Kepler 和 TESS 卫星的陆续发射,对恒星耀斑的研究也越来越多.…”

Section: 当然该理论模型是在较强的前提假设和模拟近似unclassified