Period spacings in red giants; III. Coupling factors of mixed modes

TL;DR

This paper introduces a new automated method to measure coupling factors of mixed modes in red giants, providing insights into their internal structure and evolution by analyzing thousands of stars.

Contribution

It develops a novel, automated technique for measuring coupling factors of mixed modes, enabling large-scale analysis and physical constraints on stellar interior regions.

Findings

Coupling factors vary with stellar mass and evolutionary stage.

Weak coupling observed in the most evolved red giant stars.

Large coupling factors found at subgiant-red giant transition and in red clump stars.

Abstract

The power of asteroseismology relies on the capability of global oscillations to infer the stellar structure. For evolved stars, we benefit from unique information directly carried out by mixed modes that probe their radiative cores. This third article of the series devoted to mixed modes in red giants focuses on their coupling factors that remained largely unexploited up to now. With the measurement of the coupling factors, we intend to give physical constraints on the regions surrounding the radiative core and the hydrogen-burning shell of subgiants and red giants. A new method for measuring the coupling factor of mixed modes is set up. It is derived from the method recently implemented for measuring period spacings. It runs in an automated way so that it can be applied to a large sample of stars. Coupling factors of mixed modes were measured for thousands of red giants. They show specific variation with mass and evolutionary stage. Weak coupling is observed for the most evolved stars on the red giant branch only; large coupling factors are measured at the transition between subgiants and red giants, as well as in the red clump. The measurement of coupling factors in dipole mixed modes provides a new insight into the inner interior structure of evolved stars. While the large frequency separation and the asymptotic period spacings probe the envelope and the core, respectively, the coupling factor is directly sensitive to the intermediate region in between and helps determining its extent. Observationally, the determination of the coupling factor is a prior to precise fits of the mixed-mode pattern, and can now be used to address further properties of the mixed-mode pattern, as the signature of the buoyancy glitches and the core rotation.