Probing Colliding Wind Binaries with High-Resolution X-ray Spectra

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Transcription:

Probing Colliding Wind Binaries with High-Resolution X-ray Spectra David Henley Collaborators: Ian Stevens University of Birmingham Julian Pittard University of Leeds Mike Corcoran GSFC Andy Pollock XMM-SOC@ESA-Vilspa

Importance of high-resolution X-ray spectra Chandra & XMM-Newton gratings can resolve line shifts/widths down to a few hundred km s -1 Probe dynamics of wind-wind collision Forbidden-intercombination-resonance (f-i-r) triplets from He-like ions Diagnostics of electron density, UV radiation field & temperature New insights into location, geometry, structure and dynamics of wind-wind collision

Chandra observation of γ 2 Velorum (WC8+O7.5) Observation length: 65 ks

γ 2 Velorum (2) Line fitting procedure Select narrow wavelength range around line of interest Fit to line using Gaussian line profile(s) Measure line centroid shifts and line widths

γ 2 Velorum (3) Line fitting results Lines generally unshifted Mean FWHM = 1200 km s -1 No correlation with ionization potential or wavelength

γ 2 Velorum (4) Geometrical model for line profiles Assume X-ray emission region is a conical surface Line centroid shift: v = v 0 cos β cos γ Line width: FWHM = v 0 sin β sin γ γ well-known from orbit Find that β > 85 0 Evidence of sudden radiative braking?

γ 2 Velorum (5) sudden radiative braking (Owocki & Gayley 1995; Gayley et al. 1997) Wind of WR star rapidly decelerated as it encounters O star radiation field Increases shock opening angle V444 Cygni Alters Mach number of wind-wind collision As well as affecting X-ray emission, may also affect nonthermal radio emission Spectral index depends on electron energy distribution, which depends on shock compression ratio Variability of nonthermal radio flux depends on shock opening angle (absorption effects)

γ 2 Velorum (6) ATCA radio observations (Chapman et al. 1999) Pre-periastron Post-periastron Nonthermal Thermal Modelled using thermal + nonthermal emission Data taken at different orbital phases Optical depth for nonthermal emission varies throughout orbit (depends on shock opening angle) Better orbital coverage (Dougherty et al.) shows no evidence of nonthermal emission

WR 140 (WC7 + O4.5) Chandra grating data (Pollock et al., in prep.) Correlation between line widths and ionization potential Disagrees with predictions of numerical model Evidence of non-equilibirum ionization? (Higher-excitation ions originate in faster-moving gas further from line of centres)

WR 140 (2) Spherical or disk-like winds? X-ray emission modelled assuming spherical winds White & Becker (1995) unable to explain radio light curve using spherical winds They suggest that the WR star s wind is disk-like Model of X-ray emission lines disagrees with Chandra observation Maybe X-ray emission lines can be explained by a disk-like WR wind Radio emission need to consider thermal + nonthermal emission Maybe radio emission can be explained by spherical winds More detailed modelling of X-ray & radio required More spectral information from radio would also be useful

Conclusions High-resolution X-ray spectra probe structure & dynamics of wind-wind collision Provides information on shock geometry Shock opening angle influences variability of nonthermal radio emission Final comment: Line emission generally considered to be thermal, but ions may also be excited by collisions with nonthermal electrons If relative abundance of nonthermal electrons is large, they will have to be included in the models

Modelling X-ray line profiles from CWBs (Henley, Stevens & Pittard 2003) Line profile calculations based on hydro simulations Each grid cell produces Gaussian line profile Width of Gaussian depends on temperature Height of Gaussian depends on temperature, density and optical depth Sum over whole grid to get the observed profile

Orbital variability of X-ray line profiles

γ 2 Velorum (WC8+O7.5) Basic parameters Distance = 258 pc (Hipparcos) [Evidence that it may be further away: 400 pc (Pozzo et al. 2000)] Period = 78.53 days, e = 0.326, i = 63 0 (Schmutz et al. 1997, de Marco & Schmutz 1999) L X = 1.1 10 32 erg s -1 (absorbed) L X = 16 10 32 erg s -1 (intrinsic)

γ 2 Velorum ASCA data (Stevens et al. 1996, Rauw et al. 2000)

γ 2 Velorum Line profile modelling

WR 140 VLA observations (White & Becker 1995)

η Carinae Comparing model line profiles to set of Chandra grating observations Line shapes & variations provide important probe of shock dynamics Offers another tool for constraining parameters of this mysterious star

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