Exploring masses and CNO surface abundances of red giant stars

TL;DR

This study presents a grid of stellar evolution models for 1.2-7 solar mass stars, focusing on estimating masses and CNO surface abundances of observed red giants, highlighting the need for extra mixing and reaction rate effects.

Contribution

It introduces an improved method for determining stellar masses by comparing observations with extended evolutionary tracks and analyzes CNO surface abundances in red giants.

Findings

Extra mixing is necessary to explain oxygen isotopic ratios.

Proton capture reaction uncertainties affect nitrogen and oxygen isotope predictions.

Enhanced models improve mass estimates and surface abundance interpretations.

Abstract

A grid of evolutionary sequences of stars in the mass range $1.2$-$7$ M$_{\odot}$, with solar-like initial composition is presented. We focus on this mass range in order to estimate the masses and calculate the CNO surface abundances of a sample of observed red giants. The stellar models are calculated from the zero-age main sequence till the early asymptotic giant branch (AGB) phase. Stars of M $\leqslant$ $2.2$M$_{\odot}$ are evolved through the core helium flash. In this work, an approach is adopted that improves the mass determination of an observed sample of 21 RGB and early AGB stars. This approach is based on comparing the observationally derived effective temperatures and absolute magnitudes with the calculated values based on our evolutionary tracks in the Hertzsprung-Russell diagram. A more reliable determination of the stellar masses is achieved by using evolutionary tracks extended to the range of observation. In addition, the predicted CNO surface abundances are compared to the observationally inferred values in order to show how far standard evolutionary calculation can be used to interpret available observations and to illustrate the role of convective mixing. We find that extra mixing beyond the convective boundary determined by the Schwarzschild criterion is needed to explain the observational oxygen isotopic ratios in low mass stars. The effect of recent determinations of proton capture reactions and their uncertainties on the $^{16}$O$/^{17}$O and $^{14} $N$/^{15}$N ratios is also shown. It is found that the $^{14}$N$($ p$,\gamma)^{15}$O reaction is important for predicting the $^{14}$N$/^{15}$N ratio in red giants.