A rotational line CO cooling rate prescription for AGB outflows

TL;DR

This paper develops a new CO cooling rate prescription tailored for AGB star outflows, improving the accuracy of modeling their thermal environments compared to existing ISM-based rates.

Contribution

It introduces a novel CO cooling rate prescription specifically designed for AGB outflows, validated through NLTE radiative transfer calculations.

Findings

Existing ISM cooling rates are only approximately valid for AGB conditions.

Significant deviations occur when applying ISM rates outside their intended regime.

The new prescription improves the accuracy of thermal modeling in AGB outflows.

Abstract

Asymptotic Giant Branch (AGB) stars significantly contribute to the chemical composition of the universe. In their outflows, complex chemistry takes place, which critically depends on the local temperature. Therefore, if we want to accurately model the AGB environment, we need accurate cooling rates. The CO molecule is abundant in AGB outflows, and has a dipole moment, which enables it to cool through emission from its rotational transitions. We therefore expect it to significantly contribute to cooling in this environment, even at low temperatures ($10$ K $\leqslant T\leqslant 3000$ K). Currently, CO cooling rates are available for ISM-like conditions, which encompasses a different parameter regime, with generally lower densities and velocity gradients, compared to AGB winds. Therefore, these ISM cooling rates might not be applicable to the AGB regime. In this paper, we compute CO cooling rates for hydrodynamics simulations of AGB outflows. To evaluate the net cooling rate, we calculate the energy level distribution of CO self-consistently, using the non Local Thermodynamical Equilibrium (NLTE) line radiative transfer code Magritte. We verify whether already existing CO cooling rate prescriptions for the interstellar medium (ISM) are applicable for this regime. We noticed minor differences between these prescriptions and our calculated cooling rates in general. However, when used far outside their originally intended parameter regimes, significant differences occur. Therefore, we propose a new CO cooling rate prescription for the AGB environment and we study how the computed cooling rate varies depending on input parameters.