TY - JOUR
T1 - Probing the mass-loss history of AGB and red supergiant stars from CO rotational line profiles. II. CO line survey of evolved stars
T2 - derivation of mass-loss rate formulae
AU - De Beck, E.
AU - Decin, L.
AU - de Koter, A.
AU - Justtanont, K.
AU - Verhoelst, T.
AU - Kemper, F.
AU - Menten, K. M.
PY - 2010
Y1 - 2010
N2 - Context. The evolution of intermediate and low-mass stars on the asymptotic giant branch is dominated by their strong dust-driven
winds. More massive stars evolve into red supergiants with a similar envelope structure and strong wind. These stellar winds are a
prime source for the chemical enrichment of the interstellar medium.
Aims. We aim to (1) set up simple and general analytical expressions to estimate mass-loss rates of evolved stars, and (2) from those
calculate estimates for the mass-loss rates of the asymptotic giant branch, red supergiant, and yellow hypergiant stars in our galactic
sample.
Methods. The rotationally excited lines of carbon monoxide (CO) are a classic and very robust diagnostic in the study of circumstellar
envelopes. When sampling different layers of the circumstellar envelope, observations of these molecular lines lead to detailed profiles
of kinetic temperature, expansion velocity, and density. A state-of-the-art, nonlocal thermal equilibrium, and co-moving frame
radiative transfer code that predicts CO line intensities in the circumstellar envelopes of late-type stars is used in deriving relations
between stellar and molecular-line parameters, on the one hand, and mass-loss rate, on the other. These expressions are applied to our
extensive CO data set to estimate the mass-loss rates of 47 sample stars.
Results. We present analytical expressions for estimating the mass-loss rates of evolved stellar objects for 8 rotational transitions of
the CO molecule and thencompare our results to those of previous studies. Our expressions account for line saturation and resolving
of the envelope, thereby allowing accurate determination of very high mass-loss rates. We argue that, for estimates based on a single
rotational line, the CO(2–1) transition provides the most reliable mass-loss rate. The mass-loss rates calculated for the asympotic giant
branch stars range from 4 × 10−8 M yr−1 up to 8 × 10−5 M yr−1. For red supergiants they reach values between 2 × 10−7 M yr−1
and 3 × 10−4 M yr−1. The estimates for the set of CO transitions allow time variability to be identified in the mass-loss rate. Possible
mass-loss-rate variability is traced for 7 of the sample stars. We find a clear relation between the pulsation periods of the asympotic
giant branch stars and their derived mass-loss rates, with a levelling off at ∼3 × 10−5 M yr−1 for periods exceeding 850 days.
Conclusions.
AB - Context. The evolution of intermediate and low-mass stars on the asymptotic giant branch is dominated by their strong dust-driven
winds. More massive stars evolve into red supergiants with a similar envelope structure and strong wind. These stellar winds are a
prime source for the chemical enrichment of the interstellar medium.
Aims. We aim to (1) set up simple and general analytical expressions to estimate mass-loss rates of evolved stars, and (2) from those
calculate estimates for the mass-loss rates of the asymptotic giant branch, red supergiant, and yellow hypergiant stars in our galactic
sample.
Methods. The rotationally excited lines of carbon monoxide (CO) are a classic and very robust diagnostic in the study of circumstellar
envelopes. When sampling different layers of the circumstellar envelope, observations of these molecular lines lead to detailed profiles
of kinetic temperature, expansion velocity, and density. A state-of-the-art, nonlocal thermal equilibrium, and co-moving frame
radiative transfer code that predicts CO line intensities in the circumstellar envelopes of late-type stars is used in deriving relations
between stellar and molecular-line parameters, on the one hand, and mass-loss rate, on the other. These expressions are applied to our
extensive CO data set to estimate the mass-loss rates of 47 sample stars.
Results. We present analytical expressions for estimating the mass-loss rates of evolved stellar objects for 8 rotational transitions of
the CO molecule and thencompare our results to those of previous studies. Our expressions account for line saturation and resolving
of the envelope, thereby allowing accurate determination of very high mass-loss rates. We argue that, for estimates based on a single
rotational line, the CO(2–1) transition provides the most reliable mass-loss rate. The mass-loss rates calculated for the asympotic giant
branch stars range from 4 × 10−8 M yr−1 up to 8 × 10−5 M yr−1. For red supergiants they reach values between 2 × 10−7 M yr−1
and 3 × 10−4 M yr−1. The estimates for the set of CO transitions allow time variability to be identified in the mass-loss rate. Possible
mass-loss-rate variability is traced for 7 of the sample stars. We find a clear relation between the pulsation periods of the asympotic
giant branch stars and their derived mass-loss rates, with a levelling off at ∼3 × 10−5 M yr−1 for periods exceeding 850 days.
Conclusions.
U2 - 10.1051/0004-6361/200913771
DO - 10.1051/0004-6361/200913771
M3 - Article
SN - 0004-6361
VL - 523
SP - A18/1-A18/47
JO - Astronomy and Astrophysics
JF - Astronomy and Astrophysics
ER -