New DA white dwarf models for asteroseismology of ZZ Ceti stars

TL;DR

This paper introduces a new grid of DA white dwarf models for ZZ Ceti stars that incorporate recent advances in stellar physics, enabling more accurate asteroseismological analysis and exploring extremely thin hydrogen envelopes.

Contribution

The authors develop a comprehensive set of DA white dwarf models that include updated physics, chemical profiles, and a wide range of hydrogen envelope thicknesses, improving previous models for ZZ Ceti star analysis.

Findings

New models show significantly different pulsation periods, especially for long periods.

Chemical profiles near the core are substantially different from previous models.

Models with extremely thin H envelopes are now possible for seismological solutions.

Abstract

Asteroseismology is a powerful tool to infer the evolutionary status and chemical stratification of white dwarf (WD) stars, and to explore the physical processes that lead to their formation. This is particularly true for the variable H-rich atmosphere (DA) WDs, known as DAV or ZZ Ceti stars. We present a new grid of DA WD models that take into account the last advances in the modeling and input physics of both the progenitor and the WD stars, thus avoiding and improving several shortcomings present in the set of DA WD models employed in the asteroseismological analyses of ZZ Ceti stars we carried out in our previous works. These new models are derived from a self-consistent way with the changes in the internal chemical distribution that result from the mixing of all the core chemical components induced by mean molecular-weight inversions, from $^{22}$Ne diffusion, Coulomb sedimentation, and from residual nuclearburning. In addition, the expected nuclear-burning history and mixing events along the progenitor evolution are accounted for, in particular the occurrence of third dredge-up, which determines the properties of the core and envelope of post-AGB and white dwarf stars, as well as the WD initial-final mass relation. The range of H envelopes of our new ZZ star models extends from log(M_H/M_*)= -4 to -5, to log(M_H/M_*)= -13.5. This allows, for the first time, to consider seismological solutions for ZZ Ceti stars with extremely thin H envelopes. Our new H-burning post-AGB models predict chemical profiles of O and C near the stellar centre of ZZ Ceti stars substantially different from those we used in our previous works. We find that the pulsation periods of $g$ modes and the mode-trapping properties of the new models differ significantly from those characterizing the ZZ Ceti models of our previous works, particularly for long periods.