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X-ray flare on the single giant HR 9024

X-ray flare on the single giant HR 9024. Paola Testa (MIT) . Courtesy I. Pillitteri. umbra.nascom.nasa.gov. David Garcia-Alvarez (CfA). David Huenemoerder (MIT). Fabio Reale (Univ. Palermo). Jeremy Drake (CfA).

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X-ray flare on the single giant HR 9024

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  1. X-ray flare on the single giant HR 9024 Paola Testa (MIT) Courtesy I. Pillitteri umbra.nascom.nasa.gov David Garcia-Alvarez (CfA) David Huenemoerder (MIT) Fabio Reale (Univ. Palermo) Jeremy Drake (CfA) High resolution spectroscopy workshop - MSSL, UK, March 28 2006

  2. OUTLINE • geometry of stellar coronae: • is L > or < R ? • does it depend on activity level, evolutionary stage, stellar parameters (R, gravity, rotation, ..) ? • flare modelling as diagnostics for coronal geometry • generally yields L  Rin late-type dwarfs • the case of HR 9024: • single evolved star (G1 III); giants seem to show evidence for larger L (e.g. Ayres et al. 2003) • high resolution spectra HETG observation

  3. GEOMETRY DIAGNOSTICS from FLARE MODELING • stellar flares lightcurves analogous to solar flares • size of flaring structures inferred from light curve, in particular the e-folding decay time (e.g. Kopp & Poletto 1984, White et al. 1986, van den Oord & Mewe 1989, Reale et al.1997) • thermodynamic decay time (van den Oord & Mewe 1989, Serio et al.1991; impulsive heating): ~120 L9 (T7)-1/2 • Reale et al. (1997) take into account possible continuous heating  more realistic estimates of L (information of the trajectory of the flare in the temperature-density diagram; ; )

  4. GEOMETRY DIAGNOSTICS from FLARE MODELING • two recent examples: • Proxima Centauri (Reale et al. 2004) • T Tauri stars (Favata et al. 2005; COUP data)

  5. single evolved star (G1 III) • HETG observation (96 ks) HR 9024

  6. SPECTRUM

  7. SPECTRUM

  8. LIGHTCURVE

  9. ANALYSIS • DEM and abundances analysis • derived evolution of T and EM during the flare • fit of continuum emission, selecting line-free spectral regions : T, EM (normalization parameter)

  10. RESULTS

  11. HYDRODYNAMIC MODEL • coronal plasma confined by the B field: plasma motion and energy transport only along B field lines • 1D hydrodynamic model solving time-dependent plasma equations (density, momentum, energy) with detailed energy balance • a time-dependent heating function defines the energy release triggering the flare

  12. MODEL PARAMETERS • loop semi-length L = 1012 cm (first estimate derived from the decay time ~120 L9 (T7)-1/2 [Serio et al. 1991,Reale et al. 1997]) • initial atmosphere: hydrostatic, T=2107 K ; however initial conditions do not affect the plasma evolution after a very short time

  13. RESULTS

  14. RESULTS • loop semi-length L = 1012 cm • heating: • impulsive (20ks), shifted by 15ks preceding the beginning of the observation • located at footpoints • no sustained heating (i.e. pure cooling) • volumetric heating ~10 erg/cm3/s; heating rate ~81032 erg/s • cross-section radiusr ~ 2.31010cm, i.e. aspect ratio  ~ 0.023 (from the normalization of the model lightcurve)

  15. CONCLUSIONS • large flare, unusual in single evolved stars • very hot corona, even in quiescence • loop semi-length comparable with R • we can compare model and observation with high spectral resolution • fluorescent emission — approved Suzaku observation (independent geometry diagnostics) • recurrent pattern of lightcurve with two flares (HR9024, Prox Cen, Algol, the Sun,..) may represent a general characteristics of solar and stellar flares (as suggested by Reale et al. 2004)

  16. FLUORESCENT EMISSION 15ks

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