Evolution of Thermally Pulsing Asymptotic Giant Branch Stars I. The COLIBRI Code

TL;DR

The COLIBRI code models the TP-AGB phase of stellar evolution with detailed physics, improving accuracy in predicting stellar properties and chemical processes, and enabling efficient calibration for galaxy evolution studies.

Contribution

This paper introduces the COLIBRI code, which advances TP-AGB modeling by integrating detailed physics and on-the-fly computations, surpassing previous synthetic approaches.

Findings

Self-consistent predictions of effective temperature and surface chemistry.

Accurate modeling of hot bottom burning and nucleosynthesis.

High computational speed for calibration and population synthesis.

Abstract

We present the COLIBRI code for computing the evolution of stars along the TP-AGB phase. Compared to purely synthetic TP-AGB codes, COLIBRI relaxes a significant part of their analytic formalism in favour of a detailed physics applied to a complete envelope model, in which the stellar structure equations are integrated from the atmosphere down to the bottom of the hydrogen-burning shell. This allows to predict self-consistently: (i) the effective temperature, and more generally the convective envelope and atmosphere structures, correctly coupled to the changes in the surface chemical abundances and gas opacities; (ii) sphericity effects in the atmospheres; (iii) the core mass-luminosity relation and its break-down due to hot bottom burning (HBB) in the most massive AGB stars, (iv) the HBB nucleosynthesis via the solution of a complete nuclear network (pp chains, and the CNO, NeNa, MgAl cycles), including also the production of 7Li via the Cameron-Fowler beryllium transport mechanism; (v) the chemical composition of the pulse-driven convective zone; (vi) the onset and quenching of the third dredge-up, with a suitable temperature criterion. At the same time COLIBRI pioneers new techniques in the treatment of the physics of stellar interiors. It is the first evolutionary code ever to use accurate on-the-fly computation of the equation of state for roughly 800 atoms, ions, molecules, and of the Rosseland mean opacities throughout the deep envelope. Another distinguishing aspect of COLIBRI is its high computational speed. This feature is necessary for calibrating the uncertain parameters and processes that characterize the TP-AGB phase, a step of paramount importance for producing reliable stellar population synthesis models of galaxies up to high redshift. (abridged)