An asteroseismic age estimate of the open cluster NGC 6866 using Kepler and Gaia

TL;DR

This study uses asteroseismology of giant stars in NGC 6866 to precisely determine the cluster's age and constrain stellar physics parameters like convective-core overshoot and rotation effects, improving upon previous estimates.

Contribution

It provides the first asteroseismic age estimate for NGC 6866 and constrains stellar physics parameters, highlighting the impact of rotation and overshoot on stellar evolution models.

Findings

Cluster age estimated at 0.43 Gyr with high precision.

Convective-core overshoot must be reduced to ≤ 0.1 H_p.

Rotation effects are consistent with 3D simulations but not with 1D models.

Abstract

Asteroseismology of solar-like oscillations in giant stars allow the derivation of their masses and radii. For members of open clusters this allows an age estimate of the cluster which should be identical to the age estimate from the colour-magnitude diagram, but independent of the uncertainties that are present for that type of analysis. Thus, a more precise and accurate age estimate can be obtained. We aim to measure asteroseismic properties of oscillating giant members of the open cluster NGC 6866 and utilise these for a cluster age estimate. Model comparisons allow constraints on the stellar physics, and here we investigate the efficiency of convective-core overshoot and effects of rotation during the main-sequence, which has a significant influence on the age for these relatively massive giants. We identify six giant members of NGC 6866 and derive asteroseismic measurements for five of them. This constrains the convective-core overshoot and enables a more precise and accurate age estimate than previously possible. Asteroseismology establishes the helium-core burning evolutionary phase for the giants, which have a mean mass of 2.8 $M_{\odot}$. Their radii are significantly smaller than predicted by current 1D stellar models unless the amount of convective-core overshoot on the main sequence is reduced to $\alpha_{ov} \leq 0.1 H_p$ in the step-overshoot description. Our measurements also suggest that rotation has affected the evolution of the stars in NGC 6866 in a way that is consistent with 3D simulations but not with current 1D stellar models. The cluster age is estimated to be 0.43 $\pm$ 0.05 Gyr, significantly younger and more precise than most previous estimates. We derive a precise cluster age while constraining convective-core overshooting and effects of rotation in the models. We uncover potential biases for automated age estimates of helium-core burning stars.