Characteristics of solar-like oscillations of secondary red clump stars

TL;DR

This study models the seismic properties of secondary red clump stars, revealing how their oscillation frequencies depend on stellar parameters and how these can be used to calibrate stellar evolution models.

Contribution

It provides a detailed analysis of the seismic characteristics of SRC stars and their dependence on stellar parameters, aiding in stellar population studies and model calibration.

Findings

SRC stars form a distinct peak in seismic frequency distributions.

The location of the SRC peak depends on metallicity, mixing-length, and overshooting parameters.

The seismic features can help determine critical stellar parameters like M_{Hef} and δ_{ov}.

Abstract

We calculated the populations of core-helium-burning (CHeB) stars and found that the secondary red clump (SRC) stars can form an SRC peak in the distributions of the frequency of maximum seismic amplitude ($\nu_{max}$) and mean large-frequency separation ($\Delta\nu$) of CHeB stars when metallicity $Z \geq$ 0.02. The $\nu_{max}$ and $\Delta\nu$ of CHeB stars are dependent not only on He core mass but on H-shell burning. The SRC peak is composed of the CHeB stars with mass roughly between the critical mass M_{Hef} and M_{Hef}+0.2 while He core mass is between about 0.33 and 0.36 M_{sun}. The location of the SRC peak can be affected by the mixing-length parameter $\alpha$, metallicity $Z$, and overshooting parameter $\delta_{ov}$. A decrease in $\alpha$ or increase in $Z$ or $\delta_{ov}$ leads to a movement of the SRC peak towards a lower frequency. However, the change in $Z$ and $\alpha$ only slightly affects the value of M_{Hef} but the variation in $\delta_{ov}$ can significantly affects the value of M_{Hef}. Thus the SRC peak might aid in determining the value of M_{Hef} and calibrating $\delta_{ov}$. In addition, the effects of convective acceleration of SRC stars and the $\nu_{max}$ of `semi-degenerate' stars decreasing with mass result in the appearance of a shoulder between about 40 and 50 $\mu$hz in the \dnu{} distribution. However, the convective acceleration of stars with M < M_{Hef} leads to the deficit in the $\nu_{max}$ distribution between about 9 and 20 $\mu$hz{}. Moreover, the value of the parameter $b$ of the relation between $\nu_{max}$ and $\Delta\nu$ for the populations with M > M_{Hef} is obviously larger than that for the populations with $M <$ \dmhef{}.