DEATHSTAR: Nearby AGB stars with the Atacama Compact Array: II. CO envelope sizes and asymmetries: The S-type stars
Journal article, 2021
We aim to constrain the sizes of, and investigate deviations from spherical symmetry in, the CO circumstellar envelopes (CSEs) of 16 S-type stars, along with an additional 7 and 4 CSEs of C-type and M-type AGB stars, respectively.
Methods.
We map the emission from the CO J = 2-1 and 3-2 lines observed with the Atacama Compact Array (ACA) and its total power (TP) antennas, and fit with a Gaussian distribution in the uv- and image planes for ACA-only and TP observations, respectively. The major axis of the fitted Gaussian for the CO(2-1) line data gives a first estimate of the size of the CO-line-emitting CSE. We investigate possible signs of deviation from spherical symmetry by analysing the line profiles and the minor-to-major axis ratio obtained from visibility fitting, and by investigating the deconvolved images.
Results.
The sizes of the CO-line-emitting CSEs of low-mass-loss-rate (low-MLR) S-type stars fall between the sizes of the CSEs of C-stars, which are larger, and those of M-stars, which are smaller, as expected because of the differences in their respective CO abundances and the dependence of the photodissociation rate on this quantity. The sizes of the low-MLR S-type stars show no dependence on circumstellar density, as measured by the ratio of the MLR to terminal outflow velocity, irrespective of variability type. The density dependence steepens for S-stars with higher MLRs. While the CO(2-1) brightness distribution size of the low-density S-stars is in general smaller than the predicted photodissociation radius (assuming the standard interstellar radiation field), the measured size of a few of the high-density sources is of the same order as the expected photodissociation radius. Furthermore, our results show that the CO CSEs of most of the S-stars in our sample are consistent with a spherically symmetric and smooth outflow. For some of the sources, clear and prominent asymmetric features are observed which are indicative of intrinsic circumstellar anisotropy.
Conclusions.
As the majority of the S-type CSEs of the stars in our sample are consistent with a spherical geometry, the CO envelope sizes obtained in this paper will be used to constrain detailed radiative transfer modelling to directly determine more accurate MLR estimates for the stars in our sample. For several of our sources that present signs of deviation from spherical symmetry, further high-resolution observations would be necessary to investigate the nature of, and the physical processes behind, these asymmetrical structures. This will provide further insight into the mass-loss process and its related chemistry in S-type AGB stars.
Stars: mass-loss
Circumstellar matter
Stars: winds
outflows
Stars: AGB and post-AGB
Author
M. Andriantsaralaza
Uppsala University
S. Ramstedt
Uppsala University
Wouter Vlemmings
Chalmers, Space, Earth and Environment, Astronomy and Plasmaphysics
Taissa Danilovich
KU Leuven
Elvire de Beck
Chalmers, Space, Earth and Environment, Astronomy and Plasmaphysics
M. A. T. Groenewegen
Royal Observatory of Belgium
S. Höfner
Uppsala University
F. Kerschbaum
University of Vienna
Theo Khouri
Chalmers, Space, Earth and Environment, Astronomy and Plasmaphysics
Michael Lindqvist
Uppsala University
Matthias Maercker
Chalmers, Space, Earth and Environment, Astronomy and Plasmaphysics
Hans Olofsson
Chalmers, Space, Earth and Environment, Astronomy and Plasmaphysics
G. Quintana-Lacaci
CSIC - Instituto de Fisica Fundamental (IFF)
M. Saberi
University of Oslo
R. Sahai
Jet Propulsion Laboratory, California Institute of Technology
A. Zijlstra
University of Manchester
Astronomy and Astrophysics
0004-6361 (ISSN) 1432-0746 (eISSN)
Vol. 653 A53Subject Categories
Astronomy, Astrophysics and Cosmology
Other Physics Topics
Probability Theory and Statistics
DOI
10.1051/0004-6361/202140952