Dynamics of flares on late type dMe stars

Houdebine, E. R.

doi:10.1051/0004-6361:20021537

Cited by 29 publications

(29 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This behaviour is compatible with what is normally observed for the Ca ii H and K lines, which decay more gradually than Balmer and Helium lines (e.g. Houdebine et al 1993), consistent with an interpretation of a faster evolution of high-temperature lines in the chromosphere (Houdebine 2003). The optical spectral data allowed us to trace the chromospheric reaction to the flare (with one He ii transition line covered).…”

Section: Discussionsupporting

confidence: 89%

Multiwavelength observations of a giant flare on CN Leonis

Fuhrmeister¹,

Liefke²,

Schmitt³

et al. 2008

A&A

122

View full text Add to dashboard Cite

Section: Discussionsupporting

confidence: 89%

Multiwavelength observations of a giant flare on CN Leonis

Fuhrmeister¹,

Liefke²,

Schmitt³

et al. 2008

A&A

122

View full text Add to dashboard Cite

“…Therefore, the gas that is heated and evaporated into the newly formed loop after magnetic reconnection (Cargill & Priest 1983;Forbes & Malherbe 1986) cools and reaches the formation temperature of the Balmer series before the one of the Ca ii H & K lines. Houdebine (2003) found that the rise and decay times in the Ca ii K and Hγ lines obey good relationships, which implies that there is a well-defined underlying mechanism responsible for the flux time profiles in these lines. Our results show that the duration of flares tends to be larger when the EWRQ max of the Balmer lines is greater.…”

Section: Equivalent Widths Relative To the Quiescent Statementioning

confidence: 84%

Analysis and modeling of high temporal resolution spectroscopic observations of flares on AD Leonis

Crespo‐Chacón

Montes

García-Álvarez

et al. 2006

A&A

View full text Add to dashboard Cite

We report the results of a high temporal resolution spectroscopic monitoring of the flare star AD Leo. During 4 nights, more than 600 spectra were taken in the optical range using the Isaac Newton Telescope (INT) and the Intermediate Dispersion Spectrograph (IDS). We observed a large number of short and weak flares occurring very frequently (flare activity > 0.71 h We estimated the physical parameters of the flaring plasma by using a procedure that assumes a simplified slab model of flares. All the obtained physical parameters are consistent with previously derived values for stellar flares, and the areas -less than 2.3% of the stellar surface -are comparable with the size inferred for other solar and stellar flares. We studied the relationships between the physical parameters and the area, duration, maximum flux and energy released during the detected flares.

show abstract

“…Within a single flare, multiple peaks and changes in the decay rate are possible. Some researchers have identified as flares events in which the stellar flux rises and fades more gradually (Houdebine 2003;Tovmassian et al 2003).…”

Section: A Brief Discussion Of Stellar Variabilitymentioning

confidence: 99%

Fluctuations and Flares in the Ultraviolet Line Emission of Cool Stars: Implications for Exoplanet Transit Observations

Loyd¹,

France²

2014

ApJS

View full text Add to dashboard Cite

Variations in stellar flux can potentially overwhelm the photometric signal of a transiting planet. Such variability has not previously been well-characterized in the ultraviolet lines used to probe the inflated atmospheres surrounding hot Jupiters. Therefore, we surveyed 38 F-M stars for intensity variations in four narrow spectroscopic bands: two enclosing strong lines from species known to inhabit hot Jupiter atmospheres, C ii λλ1334, 1335 and Si iii λ1206; one enclosing Si iv λλ1393, 1402; and 36.5 Å of interspersed continuum. For each star/band combination, we generated 60 s cadence lightcurves from archival Hubble Space Telescope Cosmic Origins Spectrograph and Space Telescope Imaging Spectrograph time-tagged photon data. Within these lightcurves, we characterized flares and stochastic fluctuations as separate forms of variability. Flares: we used a cross-correlation approach to detect 116 flares. These events occur in the time-series an average of once per 2.5 hr, over 50% last 4 minutes or less, and most produce the strongest response in Si iv. If the flare occurred during a transit measurement integrated for 60 minutes, 90/116 would destroy the signal of an Earth, 27/116 Neptune, and 7/116 Jupiter, with the upward bias in flux ranging from 1% to 109% of quiescent levels. Fluctuations: photon noise and underlying stellar fluctuations produce scatter in the quiescent data. We model the stellar fluctuations as Gaussian white noise with standard deviation σ x . Maximum likelihood values of σ x range from 1% to 41% for 60 s measurements. These values suggest that many cool stars will only permit a transit detection to high confidence in ultraviolet resonance lines if the radius of the occulting disk is 1 R J . However, for some M dwarfs this limit can be as low as several R ⊕ .

show abstract

Dynamics of flares on late type dMe stars

Cited by 29 publications

References 26 publications

Multiwavelength observations of a giant flare on CN Leonis

Multiwavelength observations of a giant flare on CN Leonis

Analysis and modeling of high temporal resolution spectroscopic observations of flares on AD Leonis

Fluctuations and Flares in the Ultraviolet Line Emission of Cool Stars: Implications for Exoplanet Transit Observations

Contact Info

Product

Resources

About