# Asteroseismology of evolved stars to constrain the internal transport of   angular momentum. I. Efficiency of transport during the subgiant phase

**Authors:** P. Eggenberger, S. Deheuvels, A. Miglio, S. Ekstr\"om, C. Georgy, G., Meynet, N. Lagarde, S. Salmon, G. Buldgen, J. Montalb\'an, F. Spada, J., Ballot

arXiv: 1812.04995 · 2019-01-16

## TL;DR

This study uses asteroseismic data from Kepler to evaluate the efficiency of angular momentum transport in evolved stars during the subgiant phase, revealing different behaviors compared to red giants and highlighting the need for distinct mechanisms.

## Contribution

It provides the first detailed constraints on the efficiency of angular momentum transport during the subgiant phase using precise asteroseismic measurements.

## Key findings

- Transport efficiency increases with stellar mass during subgiant phase.
- Efficiency decreases with evolution during the subgiant phase.
- Different mechanisms may operate in subgiants and red giants.

## Abstract

Context: The observations of solar-like oscillations in evolved stars have brought important constraints on their internal rotation rates. To correctly reproduce these data, an efficient transport mechanism is needed in addition to meridional circulation and shear instability. Aims: We study the efficiency of the transport of angular momentum during the subgiant phase. Results: The precise asteroseismic measurements of both core and surface rotation rates available for the six Kepler targets enable a precise determination of the efficiency of the transport of angular momentum needed for each of these subgiants. These results are found to be insensitive to all the uncertainties related to the modelling of rotational effects before the post-main sequence phase. An interesting exception in this context is the case of young subgiants (typical values of log(g) close to 4), because their rotational properties are sensitive to the degree of radial differential rotation on the main sequence. These young subgiants constitute therefore perfect targets to constrain the transport of angular momentum on the main sequence from asteroseismic observations of evolved stars. As for red giants, we find that the efficiency of the additional transport process increases with the mass of the star during the subgiant phase. However, the efficiency of this undetermined mechanism decreases with evolution during the subgiant phase, contrary to what is found for red giants. Consequently, a transport process with an efficiency that increases with the degree of radial differential rotation cannot account for the core rotation rates of subgiants, while it correctly reproduces the rotation rates of red giant stars. This suggests that the physical nature of the additional mechanism needed for the internal transport of angular momentum may be different in subgiant and red giant stars.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1812.04995/full.md

## References

30 references — full list in the complete paper: https://tomesphere.com/paper/1812.04995/full.md

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Source: https://tomesphere.com/paper/1812.04995