Magnetic mapping of solar-type stars

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Transcription:

Magnetic mapping of solar-type stars Pascal Petit figure: M. Jardine Magnetic mapping of solar-type stars introduction: scientific context tomographic tools magnetic maps of active stars stellar differential rotation Magnetic geometry of stellar coronae 1

Introduction An active star: the Sun sunspots (Galileo 1610) differential rotation (Scheiner 1630) cyclical activity (~11 years) (Schwabe 1843) 2

Photospheric magnetic field of the Sun insidesunspots (Hale 1908) antisymetricabout the equator cyclical (~22 years) ESA / NASA Coronal magnetic field Prominences trapped in closed magnetic loops Coronal plasma ejected if reconnexion of magnetic lines solar wind controlled by open field lines ESA / NASA Angular momentum exchange between the Sun and its close environment 3

Study of stellar activity Replace the Sun in a more general context: influence of various stellar parameters (age, mass, rotation, binarity) on stellar activity distribution and evolution of starspots and surface magnetic field surface differential rotation geometry and dynamics of stellar coronal plasma Evaluate the impact of magnetic fields on stellar evolution magnetospheric accretion in young solar analogues magnetic rotational braking of active stars necessity to spatially resolve stellar photospheres and coronae Tomographic imaging of solar-type stars: basic principle 4

Doppler Imaging Spectral signatures of starspots 1. low-latitude spot Doppler Imaging Spectral signatures of starspots 2. high-latitude spot 5

Time series of intensity spectra iterative maximum entropy algorithm (Vogt & Penrod 1983) Reconstructed cool spot map Measurement of stellar magnetic fields: Zeeman effect J=1 J=0 (Zeeman 1896) broadening (or splitting) of spectral lines: field strength Polarization of spectral lines: field strength and orientation 6

extraction of Zeeman signatures: Multi-line techniques Raw spectrum 3200 lines deconvolved S/N x 30 Mean line profile G5 sec. K1 primary HR 1099 binary system Zeeman-Doppler Imaging How to reconstruct a stellar vectorial magnetogram? 1. longitude of magnetic regions 7

Zeeman-Doppler Imaging How to reconstruct a stellar vectorial magnetogram? 2. latitude of magnetic regions Zeeman-Doppler Imaging How to reconstruct a stellar vectorial magnetogram? 3. orientation of field lines 8

Time series of polarised spectra iterative maximum entropy algorithm (Donati & Brown 1997) Reconstructed magnetic map Tomographic imaging: application to active stars 9

ZDI targets: fast rotating late-type stars Young stars (P rot = 0.3 8 days) Components of close binary systems (P rot of a few days) FK Com giants(p rot of a few days) Stellar vectorial magnetograms HR 1099 Close binary K1 subgiant (+ G5 sec.) P rot = 2.83 days M ~ 1.0 M sun R ~ 3.7 R sun T ~ 4700 K giantstarspotsat high latitude azimuthal (toroidal) component of the surface field (Petit et al. 2004a) 10

Stellar magnetic cycles Sign reversal of the large-scale toroidal field II Peg, Petit et al., in prep. The case of slow rotators less information in line profiles global field still observable 11

Large-scale field of slow rotators individual active regions unresolved large-scaleinclined dipole and toroidal field still observed ξ Bootis A (young G8 dwarf, v.sini=3 km/s) (Petit et al., submitted) Stellar differential rotation 12

Differential rotation Measurement of surface shear: Track the relative motion of cool spots / magnetic regions Surface shear: ofsolar-type not correlated to rotation period weaker in close binary systems (Petit et al. 2004a,b) (AB Dor, ZAMS dwarf) Donati et al. 1999 Temperature dependence of differential rotation ZAMS single dwarfs: shear intensity increasing with T eff Barnes et al. 2005 13

fluctuations of the surface shear Magnetic tracers Strongershear for magnetic tracers Secularfluctuations of the shear. starspots (AB Dor, ZAMS dwarf) Donati, Cameron & Petit (2003) Magnetic geometry of active coronae 14

From photosphere to corona Field extrapolation using ZDI map as boundary conditions (potential field) Simulated X-ray emission: AB Dor, Jardine et al. 2002a Jardine et al. 2002b X-Ray tomography of stellar coronal plasma AB Dor: OVIII 18.97Å spectral line (Chandra observations) velocity shifts compatible with single, high-latitude (60 ), compact emitting cloud Hussain et al. 2005 15

Hα tomography of stellar prominence systems primary component (M0 dwarf) secondary component (M4 dwarf) Petit et al., in prep. Hα tomography of stellar prominence systems Location & evolution of coronal condensations prim. Mass-loss rate due to coronal mass ejections sec. Braking timescale Petit et al., in prep. 16

Perspectives Perspectives Magnetospheric accretion in young solar analogues Surface imaging using molecular Zeeman effect: magnetic structure of starspots Multi-wavelength observations: optical/x-ray 17

Hα tomography of stellar prominence systems Location & evolution of coronal condensations prim. Mass-loss rate due to coronal mass ejections sec. Braking timescale Petit et al., in prep. 18

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