Discovery of the richest pulsating ultra-massive white dwarf

TL;DR

The paper reports the discovery of 19 pulsation modes in the ultra-massive white dwarf WD J0135+5722, making it the richest pulsating ultra-massive white dwarf known, which can help probe its interior and core composition.

Contribution

It presents the first detection of numerous pulsation modes in WD J0135+5722, significantly expanding the known pulsating ultra-massive white dwarfs and enabling detailed asteroseismic studies.

Findings

Discovered 19 pulsation modes in WD J0135+5722.

WD J0135+5722 is the richest pulsating ultra-massive white dwarf known.

Estimated stellar mass around 1.12-1.15 solar masses.

Abstract

The discovery of pulsations in ultra-massive white dwarfs can help to probe their interiors and unveil their core composition and crystallized mass fraction through asteroseismic techniques. To date, the richest pulsating ultra-massive white dwarf known is BPM 37093 with 8 modes detected, for which detailed asteroseismic analysis has been performed in the past. In this work, we report the discovery of 19 pulsation modes in the ultra-massive white dwarf star WD~J0135+5722, making it the richest pulsating hydrogen-atmosphere ultramassive white dwarf known to date. %In this work, we report the discovery of pulsations in WD~J0135+5722, a hydrogen-rich ultra-massive white dwarf observed with the Gran Telescopio Canarias. This object exhibits multi-periodic luminosity variations with periods ranging from 137 to 1345 s, typical of pulsating white dwarfs in the ZZ Ceti instability strip, which is centered at $T_{\rm eff} \sim 12\,000$ K. We estimate the stellar mass of WD J0135+5722 by different methods, resulting in $M_{\star} \sim 1.12-1.14 M_{\odot}$ if the star's core is made of oxygen and neon, or $M_{\star} \sim 1.14-1.15 M_{\odot}$ if the star hosts a carbon oxygen core. Future analysis of the star periods could shed light on the core chemical composition through asteroseismology.