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A&A 377, 522-537 (2001)
DOI: 10.1051/0004-6361:20011115
Self-consistent coupling of radiative transfer and dynamics in dust-driven winds
S. Liberatore1, J.-P. J. Lafon1 and N. Berruyer21 Observatoire de Paris-Meudon, DASGAL/UMR 8633, 92195 Meudon, France
e-mail: JPJ.Lafon@obspm.fr
2 Observatoire de la Côte d'Azur, Laboratoire G. D. Cassini/UMR 6529, 06304 Nice, France
e-mail: nicole@obs-nice.fr
(Received 12 May 2000 / Accepted 3 August 2001)
Abstract
Models of stationary dust-driven winds of late-type stars are investigated.
The flow is described successively using three models which couple, in
spherical symmetry, the grain-gas dynamics
in a self-consistent way with radiative transfer.
Complete radiative transfer including multiple scattering,
absorption and thermal emission
is taken into account to determine the temperature of dust grains
which in turn governs their thermal emission.
The medium is not necessarily optically thin.
The first model is used
to check one classical hypothesis, that where the gas and the grains
expand at the same velocity, the
flow is described by a one-fluid model.
This model is then improved in a second model, to include complete momentum coupling
between gas and grains by friction.
Finally, a third model
includes grains and gas coupled
by friction as well as the effects of inertial force on grains.
By means of a numerical iteration, dynamics and radiative transfer are coupled in order
to achieve a self-consistent solution in all cases.
Even for fairly low non-zero optical depths, coupling of radiation with dynamics
is found to be important for wind models which are all
highly sensitive to input data. In conclusion, approximations
(position and momentum coupling) for the dynamics should be relaxed.
Key words: stars: mass loss -- circumstellar matter -- hydrodynamics -- radiative transfer
Offprint request: S. Liberatore, Stephane.Liberatore@obspm.fr
© ESO 2001
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