Probing the mid-layer structure of red giants I. Mixed-mode coupling factor as a seismic diagnosis

TL;DR

This paper explores how the seismic coupling factor in mixed modes of red giants can serve as a diagnostic tool for probing their internal mid-layer structures, revealing insights into convective boundaries and mixing processes.

Contribution

It provides an analytical model of the coupling factor $q$, linking it to the internal structure of evolved stars and demonstrating its potential as a diagnostic for stellar interior features.

Findings

The coupling factor $q$ is degenerate with the evanescent region thickness.

$q$ varies globally along stellar evolutionary stages.

Frequency dependence of $q$ is significant in red giants.

Abstract

The space-borne missions CoRoT and Kepler have already brought stringent constraints on the internal structure of low-mass evolved stars, a large part of which results from the detection of mixed modes. However, all the potential of these oscillation modes as a diagnosis of the stellar interior has not been fully exploited yet. In particular, the coupling factor or the gravity-offset of mixed modes, $q$ and $\varepsilon_{\rm g}$, are expected to provide additional constraints on the mid-layers of red giants, which are located between the hydrogen-burning shell and the neighborhood of the base of the convective zone. In the present paper, we investigate the potential of the coupling factor in probing the mid-layer structure of evolved stars. Guided by typical stellar models and general physical considerations, we modeled the coupling region along with evolution. We subsequently obtained an analytical expression of $q$ based on the asymptotic theory of mixed modes and compared it to observations. We show that the value of $q$ is degenerate with respect to the thickness of the coupling evanescent region and the local density scale height. A structural interpretation of the global variations in $q$ observed on the subgiant and the red giant branches, as well as on the red clump, was obtained in the light of this model. We demonstrate that $q$ has the promising potential to probe the migration of the base of the convective region as well as convective extra-mixing in evolved red giant stars with typically $\nu_{\rm max} \lesssim 100~\mu$Hz. We also show that the frequency-dependence of $q$ cannot be neglected in the oscillation spectra of such stars, which is in contrast with what is assumed in the current measurement methods. This analytical study paves the way for a more quantitative exploration of the link of $q$ with the internal properties of evolved stars using stellar models.