A new correction of stellar oscillation frequencies for near-surface effects

TL;DR

This paper introduces and evaluates two new parametrizations for correcting near-surface effects in stellar oscillation frequencies, improving the accuracy of stellar models using asteroseismic data.

Contribution

The authors propose and validate two new surface correction formulae based on Gough's (1990) models, enhancing the correction of stellar oscillation frequencies in asteroseismic analysis.

Findings

The new correction methods accurately fit solar and synthetic data.

The cubic term correction is effective and easy to implement.

The method performs well on HD52265, consistent with previous studies.

Abstract

Space-based observations of solar-like oscillations present an opportunity to constrain stellar models using individual mode frequencies. However, current stellar models are inaccurate near the surface, which introduces a systematic difference that must be corrected. We introduce and evaluate two parametrizations of the surface corrections based on formulae given by Gough (1990). The first we call a cubic term proportional to $\nu^3/\mathcal{I}$ and the second has an additional inverse term proportional to $\nu^{-1}/\mathcal{I}$, where $\nu$ and $\mathcal{I}$ are the frequency and inertia of an oscillation mode. We first show that these formulae accurately correct model frequencies of two different solar models ... We then incorporate the parametrizations into a modelling pipeline that simultaneously fits the surface effects and the underlying stellar model parameters. We apply this pipeline to synthetic observations of a Sun-like stellar model, solar observations degraded to typical asteroseismic uncertainties, and observations of the well-studied CoRoT target HD52265. For comparison, we also run the pipeline with the scaled power-law correction proposed by Kjeldsen et al. (2008). The fits to synthetic and degraded solar data show that the method is unbiased and produces best-fit parameters that are consistent with the input models and known parameters of the Sun. Our results for HD52265 are consistent with previous modelling efforts and the magnitude of the surface correction is similar to that of the Sun. The fit using a scaled power-law correction is significantly worse but yields consistent parameters ... We find that the cubic term alone is suitable for asteroseismic applications and it is easy to implement in an existing pipeline. ... This parametrization is thus a useful new way to correct model frequencies so that observations of individual mode frequencies can be exploited.