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A&A 422, 675-691 (2004)
DOI: 10.1051/0004-6361:20047187
X-ray emission lines from inhomogeneous stellar winds
L. M. Oskinova, A. Feldmeier and W.-R. HamannAstrophysik, Universität Potsdam, Am Neuen Palais 10, 14469 Potsdam, Germany
e-mail: lida@astro.physik.uni-potsdam.de
(Received 2 February 2004 / Accepted 7 April 2004)
Abstract
It is commonly adopted that X-rays from O stars are produced
deep inside the stellar wind, and transported outwards through the bulk
of the expanding matter which attenuates the radiation and affects the
shape of emission line profiles. The ability of the X-ray observatories
Chandra and XMM-Newton to resolve these lines spectroscopically provided
a stringent test for the theory of the X-ray production. It turned out
that none of the existing models was able to fit the observations
consistently. The possible caveat of these models was the underlying
assumption of a smooth stellar wind. Motivated by the evidence
that the stellar winds are in fact structured, we present a 2-D
numerical model of a stochastic, inhomogeneous wind. Small parcels of
hot, X-ray emitting gas are permeated by cool, absorbing wind material
which is compressed into thin shell fragments. Wind fragmentation alters
the radiative transfer drastically, compared to homogeneous models of
the same mass-loss rate. X-rays produced deep inside the wind, which
would be totally absorbed in a homogeneous flow, can effectively escape
from a fragmented wind. The wind absorption becomes wavelength
independent if the individual fragments are optically thick. The X-ray
line profiles are flat-topped in the blue part and decline steeply in
the red part for the winds with a short acceleration zone. For the winds
where the acceleration extends over significant distances, the lines can
appear nearly symmetric and only slightly blueshifted, in contrast to
the skewed, triangular line profiles typically obtained from homogeneous
wind models of high optical depth. We show that profiles from a
fragmented wind model can reproduce the observed line profiles from
Orionis. The present numerical modeling confirms the results
from a previous study, where we derived analytical formulae from a
statistical treatment.
Key words: stars: winds, outflows -- X-rays: stars -- line: profiles -- radiative transfer
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