Validating the 1D-3D coupling stellar models via Asteroseismology of 18 Kepler main-sequence stars

TL;DR

This study validates 1D-3D coupled stellar models using asteroseismology data from 18 Kepler stars, showing improved surface layer modeling and consistent fundamental parameter estimates across multiple pipelines.

Contribution

It demonstrates the effectiveness of 1D-3D coupling models in characterizing solar-like stars and simplifies surface term corrections compared to classical models.

Findings

Good consistency with other pipelines in parameter estimation

Surface term pattern is similar across stars with 5000-6400 K T_eff

Surface term in 1D-3D models is simpler to handle

Abstract

Standard 1D stellar evolution model has poor descriptions of the near-surface layers of stars, and this can be improved by using the atmosphere model computed from 3D hydrodynamical simulations. In this work, we validated the model inferences of the 1D-3D coupling models using 18 well-studied stars from the Kepler LEGACY Sample. We compared our estimates of the fundamental parameters determined with other six pipelines and obtained good consistency. The results indicate that the 1D-3D coupling models can be applied to characterizing solar-like stars with confidence. Our analysis showed similar pattern for the surface term in stars with effective temperature range from ~5000 K to ~6400 K, suggesting that the surface term of the 1D-3D coupling models is simpler and easier to deal with than that of models using classical atmosphere.