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A&A 409, 217-233 (2003)
DOI: 10.1051/0004-6361:20031048
Radio emission models of colliding-wind binary systems
S. M. Dougherty1, J. M. Pittard2, L. Kasian1, R. F. Coker3, P. M. Williams4 and H. M. Lloyd51 National Research Council of Canada, Herzberg Institute for Astrophysics, Dominion Radio Astrophysical Observatory, PO Box 248, Penticton, British Columbia V2A 6J9, Canada
2 Department of Physics and Astronomy, The University of Leeds, Woodhouse Lane, Leeds LS2 9JT, UK
3 Los Alamos National Laboratory, X-2 MS T-087, Los Alamos, NM 87545, USA
4 Institute for Astronomy, University of Edinburgh, Royal Observatory, Blackford Hill, Edinburgh EH9 3HJ, UK
5 Blade Interactive Studios, 274 Deansgate, Manchester M3 4JB, UK
(Received 25 April 2003 / Accepted 7 July 2003 )
Abstract
We present calculations of the spatial and spectral
distribution of the radio emission from a wide WR+OB colliding-wind
binary system based on high-resolution hydrodynamical simulations and
solutions to the radiative transfer equation. We account for both
thermal and synchrotron radio emission, free-free absorption in both
the unshocked stellar wind envelopes and the shocked gas, synchrotron
self-absorption, and the Razin effect. To calculate the synchrotron
emission several simplifying assumptions are adopted: the relativistic
particle energy density is a simple fraction of the thermal particle
energy density, in equipartition with the magnetic energy density, and
a power-law in energy. We also assume that the magnetic field is
tangled such that the resulting emission is isotropic. The
applicability of these calculations to modelling radio images and
spectra of colliding-wind systems is demonstrated with models of the
radio emission from the wide WR+OB binary
WR 147
. Its
synchrotron spectrum follows a power-law between 5 and 15 GHz but
turns down to below this at lower and higher frequencies. We find that
while free-free opacity from the circum-binary stellar winds can
potentially account for the low-frequency turnover, models that also
include a combination of synchrotron self-absorption and Razin effect
are favoured. We argue that the high-frequency turn down is a
consequence of inverse-Compton cooling. We present our resulting
spectra and intensity distributions, along with simulated MERLIN
observations of these intensity distributions. From these we argue
that the inclination of the
WR 147
system to the plane of
the sky is low. We summarise by considering extensions of the current
model that are important for models of the emission from closer
colliding wind binaries, in particular the dramatically varying radio
emission of
WR 140
.
Key words: stars: binaries: general -- stars: early-type -- stars: individual: WR 147 -- stars: Wolf-Rayet -- radio continuum: stars
Offprint request: S. M. Dougherty, sean.dougherty@nrc.gc.ca
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