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A&A 444, 837-847 (2005)
DOI: 10.1051/0004-6361:20053520
Constraints on gamma-ray burst and supernova progenitors through circumstellar absorption lines
A. J. van Marle1, N. Langer1 and G. García-Segura21 Astronomical Institute, Utrecht University, PO Box 80000, 3508 TA, Utrecht, The Netherlands
e-mail: [A.vanMarle; N.Langer]@astro.uu.nl
2 Instituto de Astronomía-UNAM, APDO Postal 877, Ensenada, 22800 Baja California, Mexico
e-mail: ggs@astrosen.unam.mx
(Received 26 May 2005 / Accepted 27 July 2005 )
Abstract
Long gamma-ray bursts are thought to be caused by a subset of exploding Wolf-Rayet stars.
We argue that the circumstellar absorption lines in early supernova
and in gamma-ray burst afterglow spectra may allow us to determine the main properties
of the Wolf-Rayet star progenitors which can produce those two events.
To demonstrate this, we first simulate the hydrodynamic evolution of the circumstellar
medium around a 40
star from the creation and evolution of a wind-blown,
photo-ionized bubble around the star up to the time of the supernova explosion.
Knowledge of density, temperature, and radial velocity of the circumstellar matter as function
of space and time allows us to compute the column density in the line of sight to the
centre of the nebula, as a function of radial velocity, angle, and time.
While without radiative transfer modeling and without detailed knowledge of the spatial
distribution of chemical elements we cannot produce spectra, our column density
profiles indicate the possible number, strengths, widths, and
velocities of absorption line components
in supernova and gamma-ray burst afterglow spectra.
Our example calculation shows four distinct line features during the Wolf-Rayet stage,
at about 0, 50, 150-700, and 2200
, with only those of the lowest and highest
velocity present at all times.
The 150-700
feature decays rapidly as a function of time after the onset of the
Wolf-Rayet stage. It consists of a variable
number of components, and, especially in its evolved stage,
depends strongly on the particular line of sight.
A comparison with absorption lines detected in the afterglow of
GRB 021004
suggests that the high velocity absorption component in
GRB 021004
may be attributed to the free streaming
Wolf-Rayet wind, which is consistent with the steep density drop
indicated by the afterglow light curve.
The presence of the intermediate velocity components implies
that the duration of the Wolf-Rayet phase of the progenitor of
GRB 021004
was much smaller than the average Wolf-Rayet life time,
which strongly constrains its progenitor evolution.
Key words: stars: winds, outflows -- stars: Wolf-Rayet -- stars: supernovae: general -- gamma rays: bursts -- line: profiles -- ISM: bubbles
SIMBAD Objects
© ESO 2005
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