Models of circumstellar molecular radio line emission: Mass loss rates for a sample of bright carbon stars

TL;DR

This study models circumstellar CO radio line emission from bright carbon stars to determine key parameters like mass loss rates, revealing correlations with stellar pulsation, luminosity, and expansion velocity, and highlighting the variability in physical conditions.

Contribution

It provides detailed radiative transfer models to estimate mass loss rates and physical conditions in circumstellar envelopes of bright carbon stars, covering a wide range of mass loss rates.

Findings

Mass loss rates range from 5E-9 to 2E-5 solar masses per year.

Mass loss rate correlates with pulsational period and luminosity.

Physical conditions vary significantly across the sample.

Abstract

Using a detailed radiative transfer analysis, combined with an energy balance equation for the gas, we have performed extensive modelling of circumstellar CO radio line emission from a large sample of optically bright carbon stars. We determine some of the basic parameters that characterize circumstellar envelopes (CSEs), e.g., the stellar mass loss rate, the gas expansion velocity, and the kinetic temperature structure of the gas. The derived mass loss rates span almost four orders of magnitude, from 5E-9 up to 2E-5 solar masses per year, with the median mass loss rate being 3E-7 solar masses per year. We estimate that the estimated mass loss rates are typically accurate to 50% within the adopted circumstellar model. The physical conditions prevailing in the CSEs vary considerably over such a large range of mass loss rates. Among other things, it appears that the dust-to-gas mass ratio and/or the dust properties change with the mass loss rate. We find that the mass loss rate and the gas expansion velocity are well correlated, and that both of them clearly depend on the pulsational period and (with larger scatter) the stellar luminosity. Moreover, the mass loss rate correlates weakly with the stellar effective temperature, in the sense that the cooler stars tend to have higher mass loss rates, but there seems to be no correlation with the stellar C/O-ratio. We conclude that the mass loss rate increases with increased regular pulsation and/or luminosity, and that the expansion velocity increases as an effect of increasing mass loss rate (for low mass loss rates) and luminosity.