Asteroseismic and orbital analysis of the triple star system HD 188753 observed by Kepler

TL;DR

This study combines asteroseismic and orbital data from Kepler observations to precisely determine the fundamental parameters of the triple star system HD 188753, including stellar masses, ages, and orbital inclination.

Contribution

It presents a novel integrated analysis of asteroseismic and orbital data to accurately characterize a complex triple star system, improving parameter estimates and understanding of system dynamics.

Findings

Stellar masses are determined with high precision.

The total system mass matches orbital analysis results.

The system's orbital inclination suggests a non-coplanar configuration.

Abstract

The NASA Kepler space telescope has detected solar-like oscillations in several hundreds of single stars, thereby providing a way to determine precise stellar parameters using asteroseismology. In this work, we aim to derive the fundamental parameters of a close triple star system, HD 188753, for which asteroseismic and astrometric observations allow independent measurements of stellar masses. We used six months of Kepler photometry available for HD 188753 to detect the oscillation envelopes of the two brightest stars. For each star, we extracted the individual mode frequencies by fitting the power spectrum using a maximum likelihood estimation approach. We then derived initial guesses of the stellar masses and ages based on two seismic parameters and on a characteristic frequency ratio, and modelled the two components independently with the stellar evolution code CESTAM. In addition, we derived the masses of the three stars by applying a Bayesian analysis to the position and radial-velocity measurements of the system. Based on stellar modelling, the mean common age of the system is $10.8 \pm 0.2\,$Gyr and the masses of the two seismic components are $M_A =$ $0.99 \pm 0.01\,M_\odot$ and $M_{Ba} =$ $0.86 \pm 0.01\,M_\odot$. From the mass ratio of the close pair, $M_{Bb}/M_{Ba} = 0.767 \pm 0.006$, the mass of the faintest star is $M_{Bb} =$ $0.66 \pm 0.01\,M_\odot$ and the total seismic mass of the system is then $M_{syst} =$ $2.51 \pm 0.02\,M_\odot$. This value agrees perfectly with the total mass derived from our orbital analysis, $M_{syst} =$ $2.51^{+0.20}_{-0.18}\,M_\odot$, and leads to the best current estimate of the parallax for the system, $\pi = 21.9 \pm 0.2\,$mas. In addition, the minimal relative inclination between the inner and outer orbits is $10.9^\circ \pm 1.5^\circ$, implying that the system does not have a coplanar configuration.