An empirical view of the extended atmosphere and inner envelope of the AGB star R Doradus I. Physical model based on CO lines

TL;DR

This study uses ALMA observations and 3D radiative transfer modeling to empirically characterize the complex inner atmosphere and outflow of the AGB star R Doradus, revealing detailed velocity and density structures.

Contribution

It provides the first detailed empirical model of R Dor's extended atmosphere using multiple CO lines and 3D radiative transfer, highlighting the velocity field and density profiles.

Findings

Complex velocity field with structure down to observational resolution.

Steep temperature and density profiles near the star, shallower beyond 1.6 stellar radii.

Detection of emission blobs with higher density and velocity, indicating dynamic structures.

Abstract

The mass loss experienced on the asymptotic giant branch (AGB) at the end of the lives of low- and intermediate-mass stars is widely accepted to rely on radiation pressure acting on dust grains formed in the extended AGB atmospheres. The interaction of convection, stellar pulsation, and heating and cooling processes cause the density, velocity and temperature distributions in the inner regions of the envelope to be complex, making the dust-formation process difficult to calculate. Hence, characterising the extended atmospheres and inner outflow empirically is paramount to advance our understanding of the dust-formation and wind-driving processes. To this end, we observe the AGB star R Dor using ALMA and modelled the $^{12}$CO $v=0, J=2-1$, $v=1, J=2-1$ and $3-2$ and $^{13}$CO $v=0, J=3-2$ lines using the 3D radiative transfer code LIME up to a distance of $\sim 4$ times the radius of the star at sub-mm wavelengths. We find a complex velocity field with structure down to scales at least equal to the resolution of the observations. The observed maps are well reproduced assuming spherical symmetry for the gas temperature and density distributions. We find the radial profiles of these two quantities to be very steep close to the star and shallower for radii larger than $\sim 1.6$ times the stellar sub-mm radius. This change is consistent with the transition between extended atmosphere and outflow. We constrain the standard deviation of the stochastic velocity distribution in the large-scale outflow to be $\lesssim 0.4$ km/s. We observe two emission blobs in the CO $v=0, J=2-1$ line and find their gas densities and radial velocities to be substantially larger than those of the surrounding gas. Monitoring the evolution of these blobs will lead to a better understanding of the role of these structures in the mass-loss process of R Dor.