We consider the consequences of appreciable line optical depth for the
profile shape of X-ray emission lines formed in stellar winds. The hot gas is
thought to arise in distributed wind shocks, and the line formation is
predominantly via collisional excitation followed by radiative decay. Such
lines are often modelled as optically thin, but the theory has difficulty
matching resolved X-ray line profiles. We suggest that for strong lines of
abundant metals, newly created photons may undergo resonance scattering,
modifying the emergent profile. Using Sobolev theory in a spherically symmetric
wind, we show that thick-line resonance scattering leads to emission profiles
that still have blueshifted centroids like the thin lines, but which are
considerably less asymmetric in appearance. We focus on winds in the
constant-expansion domain, and derive an analytic form for the profile shape in
the limit of large line and photoabsorptive optical depths. Our theory is
applied to published {\it Chandra} observations of the O star $\zeta$ Pup.Comment: ApJ, in pres

Foullon, Claire

Ignace, R.

Oskinova, L.M.

Monthly Notices of the Royal Astronomical Society

English

arXiv

R. Ignace

L. M. Oskinova

C. Foullon

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Exospheric models for the X-ray emission from single Wolf-Rayet stars

Copyright © 2000 Royal Astronomical SocietyWe review existing ROSAT detections of single Galactic Wolf-Rayet (WR) stars and develop wind models to interpret the X-ray emission. The ROSAT data, consisting of bandpass detections from the ROSAT All-Sky Survey (RASS) and some pointed observations, exhibit no correlations of the WR X-ray luminosity (LX) with any star or wind parameters of interest (e.g. bolometric luminosity, mass-loss rate or wind kinetic energy), although the dispersion in the measurements is quite large. The lack of correlation between X-ray luminosity and wind parameters among the WR stars is unlike that of their progenitors, the O stars, which show trends with such parameters. In this paper we seek to (i) test by how much the X-ray properties of the WR stars differ from the O stars and (ii) place limits on the temperature TX and filling factor fX of the X-ray-emitting gas in the WR winds. Adopting empirically derived relationships for TX and fX from O-star winds, the predicted X-ray emission from WR stars is much smaller than observed with ROSAT. Abandoning the TX relation from O stars, we maximize the cooling from a single-temperature hot gas to derive lower limits for the filling factors in WR winds. Although these filling factors are consistently found to be an order of magnitude greater than those for O stars, we find that the data are consistent (albeit the data are noisy) with a trend of in WR stars, as is also the case for O stars

Open Research Exeter

Profile Shapes for Optically Thick X-ray Emission Lines from Stellar
  Winds

Profile Shapes for Optically Thick X-ray Emission Lines from Stellar Winds

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Open Research Exeter